The NOP receptor involvement in both withdrawal- and CCk-8-induced contracture responses of guinea pig isolated ileum after acute activation of κ-opioid receptor.

In isolated guinea-pig ileum (GPI), the κ-opioid acute withdrawal response is under the control of several neuronal signaling systems, including the µ-opioid, the A(1)-adenosine and the CB(1) receptors, which are involved in the inhibitory control of the κ-withdrawal response. After κ-opioid system stimulation, indirect activation of µ-opioid, A(1)-adenosine and CB(1) systems is prevented by the peptide cholecystokinin-8 (CCk-8). In the present study, we have investigated whether the NOP system is also involved in the regulation of the acute κ-withdrawal response. Interestingly, we found that in GPI preparation, the NOP system is not indirectly activated by the κ-opioid receptor stimulation, but instead this system is able by itself to directly regulate the acute κ-withdrawal response. Specifically, our results clearly highlight first the existence of an endogenous tone of the NOP system in GPI, and second that it behaves as a functional anti-opioid system. We also found that, the NOP receptor system is involved in the regulation of the CCk-8-induced contracture intensity, only when in the presence of the κ-opioid receptor stimulation. This effect seems to be regulated by an activation threshold mechanism. In conclusion, the NOP system could act as neuromodulatory system, whose action is strictly related to the modulation of both excitatory and inhibitory neurotransmitters released in GPI enteric nervous system.

Biphasic regulation of the acute µ-withdrawal and CCk-8 contracture responses by the ORL-1 system in guinea pig ileum.

The cloning of the opioid-receptor-like receptor (ORL-1) and the identification of the orphaninFQ/nociceptin (OFQ/N) as its endogenous agonist has revealed a new G-protein-coupled receptor signalling system. The structural and functional homology of ORL-1 to the opioid receptor systems has posed a number of challenges in the understanding the often competing physiological responses elicited by these G-protein-coupled receptors. We had previously shown that in guinea pig ileum (GPI), the acute µ-withdrawal response is under the inhibitory control of several systems. Specifically, we found that the exposure to a µ-opioid receptor agonist activates indirectly the κ-opioid, the A(1)-adenosine and the cannabinoid CB(1) systems, that in turn inhibit the withdrawal response. The indirect activation of these systems is prevented by the peptide cholecystokinin-8 (CCk-8). In the present study, we have investigated whether the ORL-1 system is also involved in the regulation of the acute µ-withdrawal response. Interestingly, we found that in GPI preparation, the ORL-1 system is not indirectly activated by the µ-opioid receptor stimulation, but instead the system is able by itself to directly regulate the acute µ-withdrawal response. Moreover, we have demonstrated that the ORL-1 system behaves both as anti-opioid or opioid-like system based on the level of activation. The same behaviour has also been observed in presence of CCk-8. Furthermore, in GPI, the existence of an endogenous tone of the ORL-1 system has been demonstrated. We concluded that the ORL-1 system acts as a neuromodulatory system, whose action is strictly related to the modulation of excitatory neurotrasmitters released in GPI enteric nervous system.

Acute withdrawal induced by adenosine A-receptor activation in isolated guinea-pig ileum: role of opioid receptors and effect of cholecystokinin.

OBJECTIVES: In isolated guinea-pig ileum, the mu-opioid acute withdrawal response is under control of several neuronal systems, including the kappa-opioid and the A(1)-adenosine systems, which are involved in the mu-withdrawal response inhibitory control. After mu-opioid system stimulation, indirect activation of both kappa-opioid and A(1)-adenosine systems is prevented by the peptide cholecystokinin-8 (CCk-8). Guinea-pig ileum exposed to A(1)-adenosine agonist (CPA), shows a withdrawal contracture precipitated by the A(1)-adenosine antagonist (CPT). We investigated this response. METHODS: We investigated the involvement of the opioid system in the A(1)-adenosine acute withdrawal response in guinea-pig ileum, the potential induced cross-dependence between the A(1) and the opioid system and also the interaction between the CCk-8 and A(1) systems. KEY FINDINGS: We found that in the guinea-pig ileum preparation exposed to CPA, mu- and kappa-opioid antagonists increased the withdrawal response to CPT. Tissues exposed to CPA showed a contractile response to the opioid receptor antagonist naloxone only after complete removal of the A(1)-agonist. In the presence of CPA, the response to CCk-8 was inhibited while a significant increase in CPT response intensity was observed. CONCLUSIONS: In guinea-pig ileum, stimulation of the A(1) system indirectly activates both mu- and kappa-opioid systems; this indirect activation is significantly, albeit not completely, antagonised by CCk-8. Cross dependence between A(1) and opioid systems was also observed.

Inhibitory control of the acute mu-withdrawal response by indirectly activated adenosine A1 and kappa-opioid systems in the Guinea-pig ileum; reversal by cholecystokinin.

In the isolated guinea-pig ileum (GPI), the acute mu-opioid withdrawal response is inhibited by the kappa-opioid system, indirectly activated by the opioid agonist; yet, other inhibitory mechanisms are probably operating. On the other hand, cholecystokinin (CCK-8) strongly enhances the withdrawal response. In this study, we have shown that the adenosine A1 antagonist 8-cyclopenthyl-1,3-dimethylxantine (CPT) increased the withdrawal response in dermorphin/naloxone (NLX) tests but lacked any effect if the withdrawal tests were carried out in presence of CCK-8. In tissue preparations coming from a same animal both CPT and the kappa-opioid antagonist, nor-binaltorphimine (BNI), increased the intensity of the withdrawal responses; the effects of the two antagonists were additive. The intensity of withdrawal contractile responses in presence of CCK-8 was similar to those obtained in presence of the two antagonists. Tissue preparations tested with dermorphin/CCK-8/NLX and then washed out yielded contractile responses when subsequently challenged with CPT, BNI or BNI+CPT, with a percentage markedly higher than the percentage of the response to NLX challenge. BNI+CPT also increased the intensity of the response to NLX challenge. These data suggest that acute exposure of GPI to dermorphin induces the activation of both the adenosine A1 and kappa-opioid systems, which in turns inhibit the mu-withdrawal response. CCK-8 antagonises the inhibitory effect of the indirectly activated systems.

Involvement of the cannabinoid CB1 receptor in the opioid inhibition of the response to cholecystokinin and acute withdrawal response.

Numerous recent studies have reported major functional interactions between cannabinoid and opioid systems. These interactions can be studied in the myenteric plexus-longitudinal muscle isolated preparations. We had previously shown that in the guinea-pig ileum (GPI), the opioid acute withdrawal response is under the inhibitory control of several systems; mu-opioid agonist exposure indirectly activates the kappa-opioid system; conversely, exposure to a kappa-opioid agonist indirectly activates the mu-system; the indirectly activated opioid system inhibits the withdrawal response. The adenosine A1 system is also indirectly activated by opioids and it inhibits the withdrawal response. We had also shown that indirect activation is prevented or antagonized by cholecystokinin (CCK-8). In GPI preparations briefly exposed to the mu-agonist, dermorphine (DERM) and then challenged with naloxone (NL), the cannabinoid CB1 antagonist, SR141716 (SR), increased the withdrawal responses to NL, but only did so in presence of a kappa-opioid and an adenosine A(1) antagonist. Under similar experimental conditions, SR also enhances the kappa-opioid withdrawal response. In opioid agonist/CCK-8/NL tests, SR antagonized the inhibition of the tissue response to CCK-8 induced by the mu- or kappa-opioid agonist and increased the kappa-withdrawal response, but not the mu-withdrawal response. However, the dose-response curve against dermorphine inhibition of the response to CCK-8 was bell-shaped and the highest SR concentration also significantly decreased the mu-withdrawal response. In preparations exposed to dermorphine or to the kappa-agonist, U-50,488H, the cannabinoid agonist WIN 55,212-2 increased the opioid-induced inhibition of the tissue response to CCK-8 and decreased the NL-induced responses. These results show that opioid exposure may also activate the cannabinoid CB1 system, which leads to an inhibition of the opioid acute withdrawal response. This phenomenon and the antagonistic effect of SR on the opioid-induced inhibition of the response to CCK-8 suggest that reciprocal interaction between opioid and cannabinoid systems are operating in the enteric nervous system.

Biologic activity of the tachykinins on lamb and sheep gallbladder.

In this study, we examined the activity of the tachykinins (TKs) on lamb and sheep isolated gallbladder and whether the TKs are involved in the capsaicin-induced activity in these tissues. Substance P (SP) and physalaemin (PHYS) contracted lamb gallbladder, PHYS-induced striking tachyphylaxis. This tissue was nearly insensitive to neurokinin A (NKA), neurokinin B (NKB), septide, and capsaicin. As in lamb tissues, SP and PHYS both contracted sheep gallbladder although PHYS induced no tachyphylaxis. At doses that had no effect on lamb tissue, NKA, NKB, septide, and capsaicin contracted sheep gallbladder. Our findings indicate that TK receptors differ in adult and young ovine gallbladder. The activity of PHYS on lamb gallbladder could depend on the existence of an unusual binding site, carrying one or more residues critical for the N-terminal sequence present in PHYS but not in SP.

Intestinal motility disorder induced by free radicals: a new model mimicking oxidative stress in gut.

Literature data suggest that the inflamed intestine may be subjected to a considerable oxidative stress. Therefore, the aim of the present study was to simulate the oxidative stress in the gastrointestinal tract and to explore its effect on intestinal motility. This was attained by treating isolated segments from the rabbit jejunum and from the guinea pig ileum with 2,2'-Azobis (2-amidinopropane) dihydrochloride (ABAP), which generates peroxyl radicals by thermal decomposition. Treatment of intestinal segments with ABAP reduced the muscarinic cholinergic response to acetylcholine in both preparations and induced a dose-dependent inhibition of the spontaneous contractions in the jejunum, also in the presence of tetrodotoxin. ABAP was found to inhibit the contractile response induced by BaCl(2) in guinea pig ileum preparations. This effect was not dose-dependent and it was reversed by Bay-K 8644, which activates voltage operated L-type calcium channels. The rapid and reversible effects of ABAP suggest that it might directly affect L-type calcium channels before lipoperoxidation induction. In conclusion, the results of the present study show that ABAP could be a useful tool to simulate early contractility dysfunctions mediated by oxidative stress.

Dissociation in the effects of the D2/D3 dopaminergic agonist quinpirole on drinking and on vasopressin levels in the rat.

In the present study, we investigated the role of vasopressin in the development of quinpirole-induced hyperdipsia in the rat. We report that: (1), an acute intraperitoneal (i.p.) injection of 0.56 mg/kg of quinpirole increased plasma vasopressin (radioimmunoassay) at 15 min but not at 30 or 120 min; (2), nine daily injections of quinpirole (0.56 mg/kg, i.p.) progressively increased water intake and diuresis for a period of several hours after each treatment; (3), quinpirole hyperdipsia was associated with apparently normal levels of vasopressin (which might be considered inappropriately high in the presence of excessive drinking); (4), quinpirole reduced vasopressin and oxytocin, but not angiotensin, immunoreactivity in the supraoptic nucleus. These findings suggest that quinpirole hyperdipsia is a sound animal model of psychotic polydipsia.