Regulation of the Endogenous Opiate Signaling Pathway against Oxidative Stress and Inflammation: A Considerable Approach for Exploring Preclinical Treatment of Parkinson's Disease.

INTRODUCTION: Oxidative stress and inflammation are major factors contributing to the progressive death of dopaminergic neurons in Parkinson's disease (PD). Recent studies have demonstrated that morphine's biosynthetic pathway, coupled with nitric oxide (NO) release, is evolutionarily conserved throughout animals and humans. Moreover, dopamine is a key precursor for morphine biosynthesis. METHOD: The present study evaluated a series of preclinical experiments to evaluate the effects of low-level morphine treatment upon neuro-immune tissues exposed to rotenone and 6-OHDA as models of PD, followed by an 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide cell proliferation assay and cell/tissue computer-assisted imaging analyses to assess cell/neuronal viability. RESULTS: Morphine at normal physiological concentrations (i.e., 10-6 M and 10-7 M) provided neuroprotection, as it significantly inhibited rotenone and 6-OHDA dopaminergic insults; thereby, reducing and/or forestalling cell death in invertebrate ganglia and human nerve cells. To ensure that morphine caused this neuroprotective effect, naloxone, a potent opiate receptor antagonist, was employed and the results showed that it blocked morphine's neuroprotective effects. Additionally, co-incubation of NO synthase inhibitor L-NAME also blocked morphine's neuroprotective effects against rotenone and 6-OHDA insults. CONCLUSIONS: Taken together, the present preclinical study showed that while morphine can attenuate lipopolysaccharide-induced inflammation and cell death, both naloxone and L-NAME can abolish this effect. Preincubation of morphine precursors (i.e., L-3,4-dihydroxyphenylalanine, reticuline, and trihexyphenidyl [THP] at physiological concentrations) mimics the observed morphine effect. However, high concentrations of THP, a precursor of the morphine biosynthetic pathway, induced cell death, indicating the physiological importance of morphine biosynthesis in neural tissues. Thus, understanding the morphine biosynthetic pathway coupled with a NO signaling mechanism as a molecular target for neuroprotection against oxidative stress and inflammation in other preclinical models of PD is warranted.

Influences of Taurine Pharmacodynamics and Sex on Active Avoidance Learning and Memory.

Researchers have begun to direct their research to focus on the use of taurine as a psychopharmacotherapeutic compound to treat a wide range of health- related conditions as well as neuropathological diseases. Moreover, taurine has been shown to improve emotional and cognitive declines associated with senescence in neurotypical animal models. However, despite these advances in the field of taurine therapeutics, much less is known regarding the effects of sex and taurine on neurotypical animal models that are then manipulated, modified, and/or mutated to study human diseases. The present study sought to investigate this matter in a Long Evans Hooded rat model of mature age (i.e., postnatal day 60-90) in an active avoidance test (AAT). Rats were trained for 20 trials, given a 1 h. test break, retrained for another 20 trials, and then tested at 24 h, 48 h, and 1 week for learning and memory retention. An N = 63 rats were randomly assigned to three groups: (1) Control (n = 22), (2) Taurine Pre-Train (n = 19), and (3) Taurine Post-Train (n = 20). The aim of the present study was to determine the effects of taurine given 15 min before training when compared to being given after training but 15 min before testing at 24 h on learning and memory consolidation of the AAT. The results showed in Control rats that females had shorter latencies to cross in the shuttle box, increased rates of correct learning by the % Avoids/Escapes, and decreased rates of learning errors by the % Shocks. In Taurine Post-Train male rats, taurine treatment decreased their latency to cross in the shuttle box and their rate of learning errors by the % Shocks at 24 h and 48 h Testing, but it had no effect on their rate of correct learning by the % Avoids/Escapes when compared to Control and Taurine Pre-Train male rats. In contrast, Taurine Post-Train female rats increased their latency to cross in the shuttle box during Training, 24 h and 48 h Testing, when compared to the Control and Taurine Pre-Train female rats. Further, Taurine Post-Train female rats decreased their rate of learning % Avoids/Escapes and increased the rate of learning errors % Shocks when compared to Control female rats during Training and 24 h Testing but decreased their rate of learning % Avoids/Escapes and increased the rate of learning errors % Shocks when compared to Taurine Pre-Train female rats across all test conditions. These findings suggest that neurotypical female rats may be more sensitive to the aversive stimuli (i.e., foot shocks) used in the AAT as a motivating factor for learning that may cause paradoxical behavioral learning and memory patterns. This phenomenon raises an important concern for researchers to consider when studying learning and behavioral tests in rodents that use aversive and non-aversive stimuli or a combination of both such as in the AAT. Taurine, albeit neuroprotective, may not have as much benefit in a neurotypical animal model and may increase the susceptibility for anxiogenic behaviors and interfere with cognitive learning and memory behaviors. Therefore, the mechanistic way(s) in which taurine can treat, recovery, ameliorate, and forestall other neuropathological diseases in animal models may have different psychopharmacodynamics and psychopharmacokinetics in a neurotypical animal model and should be studied with caution. This does not preclude the continued investigation of taurine psychopharmacotherapies for neuropathological diseases but encourages the careful investigation of taurine supplementation and treatment in neurotypical animals as paradoxical behavioral and cognitive outcomes have been observed herein.

Cereal and Juice, Lead and Arsenic, Our Children at Risk: A Call for the FDA to Re-Evaluate the Allowable Limits of Lead and Arsenic That Children May Ingest.

Eliminating heavy metal contamination of foods is a goal yet to be achieved in the U.S. In recent months, efforts have been underway to have the Food and Drug Administration (FDA) re-evaluate the permissible limits of lead (Pb) and arsenic (As) allowable in cereals and juices aimed for consumption by children. This report discusses the recent scientific literature that support proposed revisions in these limits. It presents proactive suggestions for the FDA to consider in its response to concerns of ongoing Pb and As exposures in food and drinks. While more scientific studies are needed to better define 'safe' levels of Pb and As exposures and ingestion of these elements in general are neurotoxic, the higher sensitivity of children to these toxic elements makes it imperative that the FDA adjust standards to be most protective of infants, toddlers, and children.

Identification of a µ opiate receptor signaling mechanism in human placenta.

BACKGROUND: Previous studies report that genes in the morphine biosynthetic pathway have been found in placental tissue. Prior researchers have shown that kappa opioid receptors are present in human placenta. We determined if a µ opiate receptor was present and which subtype was expressed in human placenta. We also sought to demonstrate a functional µ opiate receptor in human placenta. MATERIAL/METHODS: Polymerase chain reactions as well as DNA sequencing were performed to identify the µ opiate receptor subtypes present in human placenta. The functionality of the receptor was demonstrated by real time amperometric measurements of morphine induced NO release. RESULTS: The µ4 opiate receptor sequence was present as well as the µ1 opioid receptor transcript. The addition of morphine to placental tissue resulted in immediate nitric oxide release and this effect was blocked by naloxone. CONCLUSIONS: In the present study, an intact morphine signaling system has been demonstrated in human placenta. Morphine signaling in human placenta probably functions to regulate the immune, vascular, and endocrine functions of this organ via NO.

Endogenous morphine/nitric oxide-coupled regulation of cellular physiology and gene expression: implications for cancer biology.

Cancer is a simplistic, yet complicated, process that promotes uncontrolled growth. In this regard, this unconstrained proliferation may represent primitive phenomena whereby cellular regulation is suspended or compromised. Given the new empirical evidence for a morphinergic presence and its profound modulatory actions on several cellular processes it is not an overstatement to hypothesize that morphine may represent a key chemical messenger in the process of modulating proliferation of diverse cells. This has been recently demonstrated by the finding of a novel opiate-alkaloid selective receptor subtype in human multilineage progenitor cells (MLPC). Adding to the significance of morphinergic signaling are the findings of its presence in plant, invertebrate and vertebrate cells, which also have been shown to synthesize this messenger as well. Interestingly, we and others have shown that some cancerous tissues contain morphine. Furthermore, in medullary histolytic reticulosis, which is exemplified by cells having hyperactivity, the mu3 (mu3) opiate select receptor was not present. Thus, it would appear that morphinergic signaling has inserted itself in many processes taking a long time to evolve, including those regulating the proliferation of cells across diverse phyla.

The presence of endogenous morphine signaling in animals.

Recent empirical findings have contributed valuable mechanistic information in support of a regulated de novo biosynthetic pathway for chemically authentic morphine and related morphinan alkaloids within animal cells. Importantly, we and others have established that endogenously expressed morphine represents a key regulatory molecule effecting local circuit autocrine/paracrine cellular signaling via a novel mu(3) opiate receptor coupled to constitutive nitric oxide production and release. The present report provides an integrated review of the biochemical, pharmacological, and molecular demonstration of mu(3) opiate receptors in historical linkage to the elucidation of mechanisms of endogenous morphine production by animal cells and organ systems. Ongoing research in this exciting area provides a rare window of opportunity to firmly establish essential biochemical linkages between dopamine, a morphine precursor, and animal biosynthetic pathways involved in morphine biosynthesis that have been conserved throughout evolution.

Endogenous morphine signaling via nitric oxide regulates the expression of CYP2D6 and COMT: autocrine/paracrine feedback inhibition.

We determined changes in mRNA expression in specific enzymes involved in the biosynthesis of morphine in human white blood cells via microarray. Leukocyte exposure to morphine down-regulated catechol-O-methyl transferase (COMT) and CYP2D6 by approximately 50% compared with control values. The treatment did not alter DOPA decarboxylase and dopamine beta-hydroxylase expression, demonstrating the specificity of morphine actions. The verification of the microarray data was accomplished via real-time Taqman reverse transcriptase polymerase chain reaction (RT-PCR) focused on CYP2D6 and COMT expression in different blood samples treated with morphine. The analysis showed similar changes in the expression of CYP2D6 and COMT mRNA. The expression was reduced by 47 +/- 7% for CYP2D6, substantiating the microarray finding of a 54% reduction. Furthermore, exposure of white blood cells to 10(-6) M S-nitroso-N-acetyl-DL-penicillamine (SNAP), a nitric oxide (NO) donor, reduced the expression of CYP2D6 and COMT. Prior naloxone (10(-6) M) or N-nitro-L-arginine methyl ester (L-NAME) (10(-4) M) addition abrogated morphine's down-regulating activity, demonstrating morphine was initiating its actions via stimulating constitutive NO synthase derived NO release via the mu3 opiate receptor splice variant. In the past we demonstrated that UDP-glucurosyltransferase is involved in metabolizing morphine to morphine 6-glucuronide in adrenal chromaffin cells. In the present study its expression was not found in controls and morphine-treated cells, suggesting that morphine 6-glucuronide may not be synthesized in white blood cells. Taken together, it appears that morphine has the ability to modulate its own synthesis via autocrine and paracrine signaling.

Estrogen signaling at the cell surface coupled to nitric oxide release in Mytilus edulis nervous system.

In previous studies we have demonstrated release of nitric oxide (NO) in human tissues following exposure to estrogen. We now designed experiments to determine whether estrogen is present in the neural tissue of Mytilus edulis, a marine mollusk, and whether, as in vertebrates, it stimulates constitutive NO synthase activity. After HPLC purification of 17beta-estradiol (17beta-E(2)) from M. edulis ganglionic tissue, we confirmed the presence of 17beta-E(2) by RIA and ES-Q-TOF-MS analysis. We further found that when either exogenous or endogenous (purified HPLC fraction) 17beta-E(2) was added to pedal ganglia, there was immediate concentration-dependent NO release. Furthermore, 17beta-E(2) conjugated to BSA also stimulated NO release, suggesting mediation by a membrane surface receptor. Tamoxifen, an estrogen receptor antagonist, inhibited the action of both 17beta-E(2) and 17beta-E(2) conjugated to BSA, further supporting the presence of an estrogen receptor. In addition, by Western blot analysis with anti-ER-beta antibodies, we observed a 55-kDa protein in both the membrane and cytosolic fractions in pedal ganglia as well as in human leukocytes (that have been previously shown to express ER-beta). In summary, our results suggest that a physiological dose of estrogen acutely stimulates NO release within pedal ganglia via an estrogen cell surface receptor.

Endogenous morphinergic signaling and tumor growth.

The mu3 opiate receptor subtype has been characterized by various binding assays as opiate alkaloid selective (e.g. morphine) and opioid peptide (e.g. methionine enkephalin) insensitive. This opiate receptor subtype has been found on human, including cancer cell lines, and invertebrate tissues, demonstrating that it has been conserved during evolution. Furthermore, in numerous reports, this receptor is coupled to constitutive nitric oxide release. In this regard, for example, morphine immune down regulating activities parallels those actions formerly attributed to nitric oxide. We have now identified the mu3 receptor at the molecular level and sequence analysis of the isolated cDNA suggests that it is a novel, alternatively spliced variant of the mu opiate receptor gene (MOR). Furthermore, using Northern blot, reverse transcription coupled to polymerase chain reaction (RT-PCR) and sequence analysis, we have demonstrated the expression of this new mu variant in human vascular tissue, mononuclear cells, polymorphonuclear cells, and human neuroblastoma cells. The presence of this mu splice variant, adds to the growing body of evidence supporting the hypothesis that morphine is an endogenous signaling molecule in neural, immune and vascular systems. In addition to their use in the treatment of pain, opioid peptides appear to be important in the growth regulation of normal and neoplastic tissue. This review will focus on the influence of opiate alkaloids, e.g., morphine, on tumor growth, with emphasis on immuno-regulatory and antiproliferative mechanisms.

Presence of reticuline in rat brain: a pathway for morphine biosynthesis.

We demonstrate the presence of reticuline, an isoquinoline alkaloid that was purified and identified in the rat brain. This was achieved by high-performance liquid chromatography coupled with electrochemical detection. This material was finally identified by nano-electrospray ionization quadrupole time-of-flight tandem mass spectrometry. The expression of this tetrahydroisoquinoline alkaloid in rat brain is at 12.7+/-5.4 ng/g wet tissue. Furthermore, rat chow, rat small and large intestine and bacteria cultured from these tissues did not contain either morphine or reticuline, eliminating the possibility of contamination or an exogenous source of these compounds. This finding adds information which suggests that morphine biosynthesis may occur in rat neural tissues, and that its biosynthesis pathway may be similar to that reported in the poppy plant.

Cold stress alters Mytilus edulis pedal ganglia expression of mu opiate receptor transcripts determined by real-time RT-PCR and morphine levels.

Previous pharmacological, biochemical and molecular evidence prove that mu-subtype opiate receptors and opiate alkaloids, i.e. morphine, are present in the ganglionic nervous system of the mollusk Mytilus edulis (bivalve). We now present molecular evidence on the effect of rapid temperature changes on mu opiate receptor expression and morphine levels. Using primers, a labeled Taq-Man probe derived from the human neuronal mu1 opiate receptor, and real-time RT-PCR to measure the expression of mu transcripts from Mytilus pedal ganglia, we observe, in animals placed in cold water from room temperature, an enhanced morphine and morphine 6 glucuronide level in addition to a decrease in mu opiate receptor gene expression. This study provides further evidence that mu-type opiate receptors and morphine are expressed in mollusk ganglia and appear to be involved in physiological processes responding to thermal stress.

Cyclic exercise induces anti-inflammatory signal molecule increases in the plasma of Parkinson's patients.

It has been known for many years that immune system alterations occur with Parkinson's disease (PD). Changes in lymphocyte populations in cerebrospinal fluid and blood, immunoglobulin synthesis, and cytokine and acute phase protein production have been observed in patients with PD. Hence, there is evidence for inflammation. In this report we demonstrate that cyclic exercise over months results in a significant increase in the rise of plasma anti-inflammatory signal molecules, such as interleukin-10 and adrenocorticotropin. Additionally, endogenous plasma morphine levels increase with the duration of the cyclic exercise protocol. Morphine is identified and quantified by high performance liquid chromatography coupled to electrochemical detection and nano electro-spray ionization double quadrupole orthogonal acceleration time of flight mass spectrometry. Proinflammatory cytokine, i.e., interleukin-1, interleukin-6, plasma levels did not increase. These results matched with those reported previously, demonstrating enhanced motor skills and mood elevation with this cyclic exercise protocol, suggest that this protocol induces the formation of anti-inflammatory signal molecules, which appear to be associated with alleviation of some of the clinical characteristics of PD.

Opiate alkaloids and nitric oxide production in the nematode Ascaris suum.

The tissue distribution, course of secretion, and sex differences of morphine were delineated in Ascaris suum. Nitric oxide (NO) release in various tissues in response to morphine and its metabolite morphine-6-glucuronide (M6G) were also examined. Ascaris suum of both sexes along with their incubation fluid were analyzed for morphine concentrations by high-performance liquid chromatography (HPLC) over a 5-day period. Various tissues were also dissected for HPLC and NO analysis. Morphine was found to be most prevalent in the muscle tissue, and there is significantly more morphine in females than males, probably because of the large amounts present in the female uterus. Morphine (10(-9) M) and M6G (10(-9) M) stimulated the release of NO from muscles. Naloxone (10(-7) M) and N-nitro-L-arginine methyl ester (10(-6) M) blocked (P < 0.005) morphine-stimulated NO release from A. suum muscle tissue. D-Phe-Cys-Tyr-D-Trp-Om-Thr-Pen-Thr-NH2 (CTOP) (10(-7) M) did not block morphine's NO release. However, naloxone could not block M6G-stimulated NO release by muscles, whereas CTOP (10(-7) M) blocked its release. These findings were in seeming contradiction to our earlier inability to isolate a mu opiate receptor messenger RNA by reverse transcriptase-polymerase chain reaction using a human mu primer. This suggests that a novel mu opiate receptor was possibly present and selective toward M6G.

Nitric oxide modulates the physiological control of ciliary activity in the marine mussel Mytilus edulis via morphine: novel mu opiate receptor splice variants.

OBJECTIVES: The study sought to determine how dopamine controls ganglionic processes involved with modulating lateral cilia beating via the peripheral branchial nerve. METHODS: The lateral cilia found on the gill filaments exhibit metachronal ciliary beating determined stroboscopically. Novel opiate receptors were determined pharmacologically and demonstrated by RT-PCR and sequence analysis of total RNA from Mytilus edulis visceral ganglia. RESULTS: Dopamine applied to the visceral ganglion inhibits the activity of lateral cilia in a concentration and haloperidol sensitive manner. Morphine or DAMGO significantly enhances ciliary beating in a naloxone sensitive manner, whereas L-NAME, a nitric oxide synthase inhibitor, only antagonized morphine's action. SNAP, a nitric oxide donor, also enhanced lateral ciliary beating rates. Supporting the observation, i.e., morphine sensitive nitric oxide enhancement of ciliary beating and DAMGO insensitive, that two different mu opiate receptors are present in this tissue, a 602 bp fragment of the human micro 3 opiate receptor and a 935 bp fragment, designated micro 4 have been demonstrated. CONCLUSIONS: The lateral epithelium of the gill is innervated by serotonergic, cilioexcitatory neurons and dopaminergic, cilioinhibitory neurons, originating in the visceral ganglion. This data supports previous reports that demonstrate inhibiting ganglionic dopamine release allows the serotonin signals to prevail uncontrolled, enhancing ciliary rates. Supporting the observation that two different mu opiate receptors are present in this tissue, evidence is presented that identifies a 602 bp fragment of the human micro 3 opiate receptor and a 935 bp fragment, designated micro 4. Overall, the data strongly suggests that the two alternatively spliced mu opiate receptors may be involved in the physiological regulation of lateral ciliary activity in the visceral ganglia via dopamine and nitric oxide.

Morphine down regulates human vascular tissue estrogen receptor expression determined by real-time RT-PCR.

UNLABELLED: Human vascular endothelial cells express the estrogen receptor-beta (ER-beta), which can be modulated by the opiate alkaloid morphine. OBJECTIVES: To determine if morphine is capable of down regulating the ER-beta receptor in a similar fashion as the mu opiate receptor since they are both coupled to constitutive nitric oxide synthase derived nitric oxide release. METHODS AND RESULTS: Endothelial cells obtain from human vascular tissues (saphenous vein, atria and primary saphenous vein cells) were treated with 1 uM morphine plus or minus the mu opiate receptor antagonist naloxone or CTOP (10 uM) for 24 h at 37 degrees C. Total RNA was isolated from treated and untreated primary endothelial cells, and specific primers and a probe were used to determine the ER-beta gene expression by real-time RT-PCR. Cells treated with morphine exhibited a down-regulation of ER-beta, whereas naloxone and CTOP were able to partially block the morphine effect. In addition, the 266 bp fragment generated by RT-PCR using the same primers as in the real-time PCR was sequenced and revealed a 100% sequence identity as the authentic ER-beta gene sequence. CONCLUSIONS: These results indicate that ER-beta is expressed in human vascular endothelial cells, and morphine appears to regulate this receptor in a similar fashion as the mu opiate receptor.

17-beta estradiol down regulates ganglionic microglial cells via nitric oxide release: presence of an estrogen receptor beta transcript.

OBJECTIVES: In earlier studies we have demonstrated that 17-beta-estradiol and an estrogen cell surface receptor can be found on various human cells where they are coupled to nitric oxide release. We also demonstrated the presence of estrogen signaling in Mytilus edulis ganglia. In the present report, we sought to determine a function for these ganglionic estrogen receptors, transcending a reproductive role for estrogen. MATERIAL & METHODS: Ganglionic microglial egress from excised pedal ganglia was examined microscopically following pharmacological treatments designed to determine a role for 17-beta-estradiol in microglial regulation via nitric oxide. Additionally, we examined the tissue by RT-PCR and sequence analysis for the estrogen receptor beta gene. RESULTS: In ganglia incubated with varying concentrations of 17-beta-estradiol-BSA there is a significant drop in microglial egress at the 24 hour observation period (58.7 +/- 7.4 vs. 17-beta-estradiol-BSA exposed = 14.7 +/- 1.5; P<0.01), which can be antagonized by tamoxifen and significantly diminished by L-NAME, a nitric oxide synthase inhibitor. By RT-PCR and sequence analysis Mytilus edulis pedal ganglia was found to express a 266 bp fragment of the estrogen receptor-beta gene, which exhibits 100% sequence identity with the human counterpart. CONCLUSION: These data suggest that 17-beta-estradiol-BSA is working on estrogen cell surface receptors since 17-beta-estradiol-BSA does not enter the cytoplasm and that these receptors are coupled to constitutive nitric oxide release. This study demonstrates that 17-beta-estradiol can down regulate microglial fMLP induced activation and activation following ganglionic excision.

The presence of 17-beta estradiol in Mytilus edulis gonadal tissues: evidence for estradiol isoforms.

OBJECTIVES: In earlier studies, we demonstrate that 17-beta -estradiol and an estrogen cell surface receptor can be found on various human cells, i.e., vascular endothelial, monocytes, and granulocytes, where they are coupled to nitric oxide release. We further demonstrated this phenomenon in the marine mussel Mytilus edulis ganglionic tissues. In the present report we sought to determine if estrogen can be found in M. edulis reproductive tissues. MATERIAL & METHODS: We determined the presence of 17-beta -estradiol via high pressure liquid chromatography (HPLC) and radioimmunoassay (RIA) in the animals gonads. This substance was further identified via nanoelectro-spray ionization quadrupole time of flight mass spectrometry (Q-TOF-MS). RESULTS: 17-beta -estradiol was identified and quantified in Mytilus gonads. Interestingly, we also determined that estradiol isoforms also were present in this tissue. CONCLUSION: These data demonstrate that 17-beta-estradiol and an estradiol isoform is present in M. edulis gonadal tissues, suggesting that they have functions related to reproduction. This further suggests that estrogen's association with reproductive activities has a long evolutionary history and that this association began in invertebrates.

Immunocytes modulate ganglionic nitric oxide release which later affects their activity level.

Pedal ganglia excised and maintained in culture for up to 2 h, release NO at low levels. The range can vary between 0 to 1.1 nM. Non-stimulated immunocytes do not significantly stimulate ganglionic NO release when incubated with pedal ganglia. However, ganglia exposed to immunocytes that had been previously activated by a 30 min incubation with interleukin 1 beta, release NO significantly above basal levels. In these experiments, 91 +/- 2.5% of the non-stimulated immunocytes exhibited form factors in the 0.72 to 0.89 range (sampled prior to ganglionic addition), whereas 62 +/- 10.3% of the interleukin 1 beta stimulated immunocytes had form factors in the 0.39 to 0.49 range, demonstrating activation. Addition of the nitric oxide synthase inhibitor, L-NAME (10(-4) M), inhibited basal ganglionic NO release as well as that initiated by exposing the ganglia to activated immunocytes. Interestingly, non activated immunocytes, following ganglionic exposure, exhibited activity levels in the 13% range, representing a non significant increase. Cells exposed to interleukin 1 beta had a 65% activity level at the beginning of the experiment, followed by a drop of activity to 19 +/- 3.2% after ganglionic exposure. Repeating this last observation in the presence of L-NAME (10(-4) M), brought the activity level of the immunocytes back to the pre-ganglionic exposure level of activity, demonstrating that ganglionic NO was involved in down regulating immunocyte activity.

Effects of morphine on tumour growth.

Endogenous opiate alkaloids, such as morphine, and their peptide counterparts have been implicated in a wide variety of pharmacological and physiological functions. In addition to their use in the treatment of pain, opioids, appears to be important in the growth regulation of normal and neoplastic tissue. This review will focus on the influence of endogenous and exogenous opioids on tumour growth, with emphasis on immunoregulatory and antiproliferative mechanisms.

A hormonal role for endogenous opiate alkaloids: vascular tissues.

The distribution of morphine-containing cells in the central nervous system, adrenal gland, and its presence in blood may serve to demonstrate that this signal molecule can act as a hormone besides its role in cell-to-cell signaling within the brain. This speculative review is the result of a literature evaluation with an emphasis on studies from our laboratory. Opioid peptides and opiate alkaloids have been found to influence cardiac and vascular function. They have also been reported to promote ischemic preconditioning protection in the heart. Given the presence of morphine and the novel mu(3) opiate receptor on vascular endothelial cells, including cardiac and vascular endothelial cells in the median eminence, it would appear that endogenous opiate alkaloids are involved in modulating cardiac function, possible at the hormonal level. This peripheral target tissue, via nitric oxide coupling to mu opiate receptors, may serve to down regulate the excitability of this tissue given the heart's high performance state as compared to that of the saphenous vein, a passive resistance conduit. With this in mind, morphine and other endogenous opiate alkaloids may function as a hormone.