Recent progress in the neurotoxicology of natural drugs associated with dependence or addiction, their endogenous agonists and receptors.
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Nicotine in tobacco, tetrahydrocannabinol (delta 9-THC) in marijuana and morphine in opium are well known as drugs associated with dependence or addiction. Endogenous active substances that mimic the effects of the natural drugs and their respective receptors have been found in the mammalian central nervous system (CNS). Such active substances and receptors include acetylcholine (ACh) and the nicotinic ACh receptor (nAChR) for nicotine, anandamide and CB1 for delta 9-THC, and endomorphins (1 and 2) and the mu (OP3) opioid receptor for morphine, respectively. Considerable progress has been made in studies on neurotoxicity, in terms of the habituation, dependence and withdrawal phenomena associated with these drugs and with respect to correlations with endogenous active substances and their receptors. In this article we shall review recent findings related to the neurotoxicity of tobacco, marijuana and opium, and their toxic ingredients, nicotine, delta 9-THC and morphine in relation to their respective endogenous agents and receptors in the CNS. (+info)
Activation of spinal opioid receptors contributes to hypotension after hemorrhage in conscious rats.
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Opioid receptors are activated during severe hemorrhage, resulting in sympathoinhibition and a profound fall in blood pressure. This study examined the location and subtypes of opioid receptors that might contribute to hypotension after hemorrhage. Intrathecal naloxone methiodide (100 nmol) abolished the fall in blood pressure after hemorrhage (1.5% of body wt; mean arterial pressure 122 +/- 8 mmHg after naloxone methiodide vs. 46 +/- 5 mmHg in controls, P < 0. 001). Intracisternal naloxone methiodide was less effective than intrathecal naloxone methiodide, whereas intravenous naloxone methiodide, which does not cross the blood-brain barrier, did not alter the fall in blood pressure after hemorrhage. These results demonstrate that spinal opioid receptors contribute to hypotension after hemorrhage but do not exclude supraspinal effects. In separate experiments, the subtype-specific opioid antagonists ICI-174864 (delta-antagonist), norbinaltorphimine (nor-BNI; kappa-antagonist), and H-D-Phe-Cys-Tyr-D-Trp-Orn-Thr-Pen-Thr-NH2 (CTOP; mu-antagonist) were each administered intrathecally to determine the minimum dose that would attenuate hypotension during severe hemorrhage. These antagonists were effective at similar doses (3 nmol for CTOP, 6 nmol for ICI-174864, and 10 nmol for nor-BNI), although the binding affinities of these three different agents for their target receptors varied >1600-fold. Comparisons of the minimum effective doses of these antagonists in relation to their binding affinities provides strong evidence for the participation of delta-receptors in mediating hypotension after hemorrhage. In contrast, the dose at which nor-BNI was effective suggests an effect at delta-receptors but not kappa-receptors. The efficacy of CTOP, albeit at a high dose, also suggests an effect at mu-receptors. (+info)
Antibodies and antisense oligodeoxynucleotides to mu-opioid receptors, selectively block the effects of mu-opioid agonists on intestinal transit and permeability in mice.
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1. We have studied the effects of mu and delta opioids on intestinal function (permeability, PER; gastrointestinal transit, GIT), and their antagonism after the intracerebroventricular (i.c.v.) administration of specific antibodies (ABs) or antisense oligodeoxynucleotides (ODN) to mu-receptors (OR). Central versus peripheral site/s of action of subcutaneous (s.c.) mu-opioids, were also assessed. 2. Male Swiss CD-1 mice were used. GIT was measured with charcoal and PER by the passage of 51Cr-EDTA from blood to lumen. 3. Morphine and fentanyl (i.c.v. and s.c.) inhibited GIT and PER in a dose-related manner; they were more potent by i.c.v. route, both on GIT and PER (70 and 17 times for morphine and fentanyl). They also had a greater effect on GIT than PER (4.3 and 1.6 times). DPDPE had a lower potency than mu-agonists in all experiments, and no dose-response could be obtained after s.c. administration on GIT. 4. Pretreatment with i.c.v. ABs (24 h) or antisense ODN (5 days), decreased the effects (GIT and PER) of i.c.v. morphine and fentanyl, while those of DPDPE remained unchanged. The ABs did not alter the peripheral effects of mu-opioids. 5. The results show that (i.c.v. or s.c.) mu opioids produce dose-related inhibitions of PER and GIT, being more potent by the i.c.v. route. Delta-opioids had a greater effect on PER than GIT, while the opposite occurred for mu-agonists. Pretreatment with ABs or ODN to mu-OR, blocked the central effects of mu (but not delta) agonists on GIT and PER. (+info)
In vivo signal transduction of nociceptive response by kyotorphin (tyrosine-arginine) through Galpha(i)- and inositol trisphosphate-mediated Ca(2+) influx.
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Kyotorphin is a dipeptidic neuropeptide (tyrosine-arginine) that has specific receptor coupled to G(i) and phospholipase C and elicits Met-enkephalin release. Here, we attempted to demonstrate the in vivo evidence for the presynaptic mechanism by analyzing its nociceptive responses after peripheral application. Kyotorphin elicited potent nociceptive flexor responses at extremely low doses between 0.1 and 100 fmol after the intraplantar injection into the hind-limb of mice. The site of action of kyotorphin-induced responses was identified to be on nociceptor endings, because the responses were markedly attenuated by intrathecal pretreatments with Galpha(i1) or Galpha(i2) antisense-oligodeoxynucleotides. Similar mechanisms were observed with histamine-induced nociceptive responses, except for the use of different antagonist and Galpha(q/11) antisense-oligodeoxynucleotide. Both responses were characterized to be mediated through inositol trisphosphate receptor-gated Ca(2+) influx, because they were blocked by xestospongin C, an allosteric antagonist for inositol trisphosphate receptor and EGTA, but not thapsigargin. Because the nociceptive responses by compound 48/80 through histamine-release from mast cells were completely abolished by thapsigargin, it is unlikely that the dose of thapsigargin is not sufficient to block both responses. All of these in vivo findings strongly support our previous view that kyotorphin elicits Ca(2+) influx through inositol trisphosphate receptor located at presynaptic plasma membranes. (+info)
Elf-pulsed magnetic fields modulate opioid peptide gene expression in myocardial cells.
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OBJECTIVES: Magnetic fields have been shown to affect cell proliferation and growth factor expression in cultured cells. Although the activation of endorphin systems is a recurring motif among the biological events elicited by magnetic fields, compelling evidence indicating that magnetic fields may modulate opioid gene expression is still lacking. We therefore investigated whether extremely low frequency (ELF) pulsed magnetic fields (PMF) may affect opioid peptide gene expression and the signaling pathways controlling opioid peptide gene transcription in the adult ventricular myocyte, a cell type behaving both as a target and as a source for opioid peptides. METHODS: Prodynorphin gene expression was investigated in adult rat myocytes exposed to PMF by the aid of RNase protection and nuclear run-off transcription assays. In PMF-exposed nuclei, nuclear protein kinase C (PKC) activity was followed by measuring the phosphorylation rate of the acrylodan-labeled MARCKS peptide. The effect of PMF on the subcellular distribution of different PKC isozymes was assessed by immunoblotting. A radioimmunoassay procedure coupled to reversed-phase high performance liquid chromatography was used to monitor the expression of dynorphin B. RESULTS: Here, we show that PMF enhanced myocardial opioid gene expression and that a direct exposure of isolated myocyte nuclei to PMF markedly enhanced prodynorphin gene transcription, as in the intact cell. The PMF action was mediated by nuclear PKC activation but occurred independently from changes in PKC isozyme expression and enzyme translocation. PMF also led to a marked increase in the synthesis and secretion of dynorphin B. CONCLUSIONS: The present findings demonstrate that an opioid gene is activated by myocyte exposure to PMF and that the cell nucleus and nuclear embedded PKC are a crucial target for the PMF action. Due to the wide ranging importance of opioid peptides in myocardial cell homeostasis, the current data may suggest consideration for potential biological effects of PMF in the cardiovascular system. (+info)
Intestinal transport and metabolism of glucose-conjugated kyotorphin and cyclic kyotorphin: metabolic degradation is crucial to intestinal absorption of peptide drugs.
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Intestinal transport and metabolism of modified kyotorphin (KTP) were studied in rats. Modified KTPs studied were C-terminally modified KTP with p-aminophenyl-beta-D-glucoside (KTP-pAPbeta glc), N-terminally modified KTP-pAPbeta glc with t-butyloxycarbonyl group (Boc-KTP-pAPbeta glc) and the N- and C-terminally modified KTP by cyclization (cyclic KTP). KTP-pAPbeta glc was metabolized at a similar rate to that of KTP, and did not appear on the serosal side. Although Boc-KTP-pAPbeta glc was also metabolized, it was more stable than KTP and appeared on the serosal side. Cyclic KTP was also quite stable and appeared on the serosal side. The modified KTPs were evaluated kinetically for absorption consisting of membrane transport and metabolism. Absorption clearance (CL(abs)) of cyclic KTP, Boc-KTP-pAPbeta glc and Boc-KTP was higher than that of KTP (0.247 microl/min/cm) (Mizuma et al., Biochim. Biophys. Acta 1335 (1997) 111-119), which is the theoretical maximum by complete inhibition of peptidase activity, indicating that derivatization of KTP increases the membrane permeability. Furthermore, the data clearly showed that the greater the metabolic clearance (CL(met)) of KTP and the KTP derivatives, the lower the absorption clearance (CL(abs)). These results and further simulation study led to the conclusion that metabolic degradation in the intestinal tissues is more critical than membrane permeability (transport) for oral delivery of peptide drugs. Based on the stability of cyclic KTP in serum, this appears to be a good candidate analgesic peptide drug. (+info)
Gene expression and peptide localization for LH/hCG receptor in porcine small and large luteal cells: possible regulation by opioid peptides.
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The aim of the present studies was to investigate (1) the presence of LH receptor (LHR) in porcine separated small (SLCs) and large (LLCs) luteal cells taken from mid-luteal corpora lutea and (2) the influence of opioid agonist, FK 33-824 (FK) on LHR gene expression in these cells. Immunocytochemistry revealed intense staining for LHR in both SLCs and LLCs. Reverse transcription-polymerase chain reaction (RT-PCR) and Southern hybridization were used to check the effect of FK and hCG on LHR gene expression. The LHR gene expression was observed in non-stimulated LLCs and in both types of cells after treatment with FK or hCG. FK stimulated LHR gene expression in SLCs and inhibited the gene expression in LLCs. Moreover, FK inhibited and potentiated stimulatory influence of hCG on the gene expression in LLCs and SLCs, respectively. These results suggest that LHR gene expression in porcine luteal cells can be regulated by opioid peptides. (+info)
Zinc finger-containing transcription factor GATA-4 and homeodomain Nkx-2.5 govern crucial developmental fates and have been found to promote cardiogenesis in embryonic cells exposed to the differentiating agent DMSO. Nevertheless, intracellular activators of these transcription factors are largely unknown. In this study, pluripotent P19 cells expressed the prodynorphin gene, an opioid gene encoding for the dynorphin family of opioid peptides. P19 cells were also able to synthesize and secrete dynorphin B, a biologically active end product of the prodynorphin gene. DMSO-primed GATA-4 and Nkx-2.5 gene expression was preceded by a marked increase in prodynorphin gene expression and dynorphin B synthesis and secretion. The DMSO effect occurred at the transcriptional level. In the absence of DMSO, dynorphin B triggered GATA-4 and Nkx-2.5 gene expression and led to the appearance of both alpha-myosin heavy chain and myosin light chain-2V transcripts, two markers of cardiac differentiation. Moreover, dynorphin B-exposed cells were positively stained in the presence of MF 20, a mouse monoclonal antibody raised against the alpha-myosin heavy chain. Opioid receptor antagonism and inhibition of opioid gene expression by a prodynorphin antisense phosphorothioate oligonucleotide blocked DMSO-induced cardiogenesis, suggesting an autocrine role of an opioid gene in developmental decisions. (+info)