Jacques Vignon

In vivo labelling of the mouse dopamine uptake complex with the phencyclidine derivative [3H]BTCP.

[3H]BTCP ([3H]N-[1-(2-benzo(b)thiophenyl)cyclohexyl]piperidine), a phencyclidine (PCP) derivative which binds with a high affinity to the dopamine (DA) uptake complex in vitro, has been tested for in vivo binding to mouse brain. Using [3H]BTCP as a tracer (5 microCi, i.v.) we found the striatum as the region which accumulated the largest amount of radioactivity (58 dpm/mg tissue). In other brain regions the radioactive level (about 20 dpm/mg tissue) was close to the non-specific binding determined by an injection of unlabeled BTCP (40 mg/kg, s.c.) 2 h prior to the [3H]BTCP injection. In the striatum [3H]BTCP binding was inhibited in a dose-dependent manner by unlabeled BTCP (ID50 = 6.34 mg/kg) and nomifensine (ID50 = 11.06 mg/kg). It was unaffected by the DA receptor antagonist haloperidol and by PCP or its analog TCP at doses of 10 mg/kg. These results suggest that [3H]BTCP binds to the dopamine uptake complex in the mouse brain in vivo. Thus, although PCP has no effect on [3H]BTCP binding in these experimental conditions, this in vivo binding model will be useful for the determination of the precise interaction of PCP and its derivatives with the striatal dopamine uptake complex in vivo independently of their interaction with the N-methyl-D-aspartate receptor-channel complex.

Pharmacological characterization of the discriminative stimulus properties of the phencyclidine analog, N-(1-(2-benzo(b)thiophenyl)-cyclohexyl)piperidine

Abstractu2002Rationale: Although both cocaine and the phencyclidine analog, BTCP, have dopamine (DA) re-uptake blocking properties, under some conditions their behavioral effects can be differentiated. Therefore, we examined whether the discriminative stimulus (DS) effects of BTCP are different from those of cocaine. Objectives: To compare the effects of monoamine re-uptake blockers, varying in their in vitro potencies as inhibitors of DA, norepinephrine (NE), or serotonin re-uptake, in different groups of rats trained to discriminate either BTCP or cocaine from saline. Additionally, drugs from other pharmacological classes were tested in both groups. Methods: Rats were trained to discriminate either BTCP (5 mg/kg, i.p.) or cocaine (10 mg/kg, i.p.) from saline under a two-lever FR10 drug discrimination procedure. Results: BTCP and cocaine cross-substituted in BTCP- and cocaine-trained rats. The DA re-uptake blockers, mazindol, indatraline, methylphenidate, GBR12909, and GBR12935, occasioned dose-related drug-lever (DL) selection both in cocaine- and in BTCP-trained rats, with potencies that were significantly correlated. In contrast, the NE re-uptake blockers, nisoxetine, desipramine, and nortriptyline, produced higher levels of DL selection in BTCP-trained rats than in cocaine-trained rats, a profile like that reported in low-dose cocaine-trained rats. Drugs from other classes acted similarly in both discriminations. Further, the α1-adrenergic antagonist prazosin dose dependently blocked the DS effects of the training dose of BTCP, but not of cocaine. Conclusions: Theresults suggest that the DS effects of BTCP are similar to cocaine, and resemble those of a low training dose of cocaine.

Characterization of 'non-N-methyl-D-Aspartate' binding sites for gacyclidine enantiomers in the rat cerebellar and telencephalic structures.

Gacyclidine is a non‐competitive NMDA receptor antagonist with potent neuroprotective properties. However, we have previously demonstrated that gacyclidine enantiomers [(–) and (+)GK11] interact with other (‘non‐NMDA’) binding sites which may play a role in the lower self‐neurotoxicity of this compound relative to the other NMDA receptor antagonists. Evidence for these binding sites has been obtained from autoradiographic and membrane binding experiments. They were found to be expressed at high levels in the molecular layer of the cerebellum, although they can also been seen in the granular layer and in telencephalic regions. The present study was designed to further characterize these gacyclidine ‘non‐NMDA’ binding sites. The pharmacological profiles obtained on cerebellar and telencephalic membrane homogenates showed that they could not be linked directly to the main receptors or uptake complexes of the central nervous system (CNS). However, the comparison of (–) and (+)[3H]GK11 binding distribution in different mutant animals bearing specific cellular deficits in the cerebellum has demonstrated that the gacyclidine ‘non‐NMDA’ binding sites are associated with the dendritic trees of Purkinje cells. Interestingly, our study also shows that the radioligand binding to both cerebellar and telencephalic structures could be modulated by endogeneous factors which can be removed by a stringent prewashing procedure.

Re-evaluation of phencyclidine low-affinity or "non-NMDA" binding sites.

TCP and its derivative gacyclidine (± GK11) are high‐affinity non‐competitive antagonists of N‐methyl‐D‐aspartate (NMDA) receptors (NMDARs) and as such exhibit significant neuroprotective properties. These compounds also bind with a low affinity to binding sites whose pharmacological profiles are different from that of NMDARs. With the intention to develop new strategies of neuroprotection, we found it mandatory to investigate whether 1‐[1‐(2‐thienyl)cyclohexyl]piperidine (TCP) and gacyclidine low‐affinity sites are similar. The effects of several drugs selective for either NMDARs or the [3H]TCP low‐affinity site (or PCP3 site) on (+), (−)[3H]GK11 and [3H]TCP specific binding were investigated. Competition experiments on cerebellum homogenates revealed substantial differences between the pharmacological profiles of the PCP3 site and that of gacyclidines enantiomers low‐affinity sites. Under experimental conditions preventing the interaction of the radioligands with NMDARs, the autoradiographic study showed, however, that the distributions of both [3H]TCP and (−)[3H]GK11 specific binding were similar. The specific labelling was low and uniform in telencephalic structures, whereas in the cerebellum it was higher in the molecular than in the granular layer. Finally, the analysis of competition experiments performed on tissues slices demonstrated that PCP3 selective ligands were unable to prevent [3H]TCP or (−)[3H]GK11 binding to “non‐NMDA” binding sites. As a whole, our data suggest that: (1) the different pharmacological profiles of [3H]TCP and [3H]gacyclidine enantiomers on low‐affinity sites are due to their selectivity for specific NMDARs subpopulations; (2) the pharmacological isolation of TCP and gacyclidine “non‐NMDA” binding sites is the most appropriate way to further study the low‐affinity component of their specific binding. Obtaining reliable and specific pharmacological tools for those binding sites is of particular interest, since it is likely that they play a substantial role in the low neurotoxicity, and therefore tolerability, of gacyclidine, a new neuroprotective drug currently evaluated in clinical trials for the treatment of brain and spinal cord injuries.

Development of NMDAR Antagonists with Reduced Neurotoxic Side Effects: a Study on GK11

The NMDAR glutamate receptor subtype mediates various vital physiological neuronal functions. However, its excessive activation contributes to neuronal damage in a large variety of acute and chronic neurological disorders. NMDAR antagonists thus represent promising therapeutic tools that can counteract NMDARs’ overactivation. Channel blockers are of special interest since they are use-dependent, thus being more potent at continuously activated NMDARs, as may be the case in pathological conditions. Nevertheless, it has been established that NMDAR antagonists, such as MK801, also have unacceptable neurotoxic effects. Presently only Memantine is considered a safe NMDAR antagonist and is used clinically. It has recently been speculated that antagonists that preferentially target extrasynaptic NMDARs would be less toxic. We previously demonstrated that the phencyclidine derivative GK11 preferentially inhibits extrasynaptic NMDARs. We thus anticipated that this compound would be safer than other known NMDAR antagonists. In this study we used whole-genome profiling of the rat cingulate cortex, a brain area that is particularly sensitive to NMDAR antagonists, to compare the potential adverse effects of GK11 and MK801. Our results showed that in contrast to GK11, the transcriptional profile of MK801 is characterized by a significant upregulation of inflammatory and stress-response genes, consistent with its high neurotoxicity. In addition, behavioural and immunohistochemical analyses confirmed marked inflammatory reactions (including astrogliosis and microglial activation) in MK801-treated, but not GK11-treated rats. Interestingly, we also showed that GK11 elicited less inflammation and neuronal damage, even when compared to Memantine, which like GK11, preferentially inhibits extrasynaptic NMDAR. As a whole, our study suggests that GK11 may be a more attractive therapeutic alternative in the treatment of CNS disorders characterized by the overactivation of glutamate receptors.

Does crossing over repeated treatment with the dopamine reuptake inhibitors cocaine and BTCP modify their effects on cocaine-induced locomotion?

Abstract Because the dopamine reuptake inhibitors cocaine and BTCP produce different behavioral effects after repeated administration, we studied whether they could alter each other’s effects by examining the effects of crossing over repeated treatment with cocaine and BTCP on cocaine-induced locomotion. Male C57BL/6 mice were treated repeatedly with cocaine or BTCP during a first phase (days 1–3) and 3 days later, treated repeatedly with the same or the other compound during a second phase (days 7–9), after which they were administered one of several doses of cocaine on the next day. Locomotor activity was assessed after every daily treatment. The results show that 1) cocaine induced sensitization to its locomotor effects, 2) cocaine-induced sensitization was not altered by subsequent repeated treatment with BTCP, 3) initial repeated treatment with BTCP induced apparent cross-tolerance to cocaine, and 4) the initial effects of repeated BTCP were not markedly altered by subsequent repeated treatment with cocaine. The results indicate that the initial effects produced by repeated cocaine or BTCP are enduring and relatively difficult to alter by crossing over repeated treatment with the other compound. Thus, sensitization to the locomotor effects of cocaine in mice appeared to be attenuated by prior repeated treatment with BTCP but not reversed when followed by repeated treatment with BTCP.

Inhibition of locus coeruleus neurons by the phencyclidine analog, N-[1-(2-benzo(b)thiophenyl)cyclohexyl]piperidine: evidence for potent indirect adrenoceptor agonist properties

The effects of the phencyclidine derivative, N-[1-(2-benzo(b)thiophenyl)cyclohexyl]piperidine (BTCP), on the electrical activity of noradrenaline (NA) neurons of the locus coeruleus (LC) were studied in halothane-anesthetized rats. Systemic administration of BTCP potently inhibited LC neurons (ID50 of 1.1 +/- 0.1 mg/kg i.v.). This effect was mimicked by local microejection of BTCP into the LC. Both the systemic and local effects of BTCP were blocked by alpha 2-adrenoceptor antagonists and prevented by prior depletion of catecholamines with reserpine. These and other data suggest that BTCP behaves as a potent indirect NA agonist (i.e. via NA re-uptake and/or release systems).

Differential Interaction of Phencyclidine (PCP) with the Dopamine Uptake Complex and the PCP Receptor in vivo

ABSTRACT The Phencyclidine (PCP) derivatives [3H]BTCP and [3H]TCP were used to label in vivo the DA uptake complex and the NMDA receptor-associated PCP receptor, respectively, and to study the dual interaction of PCP-like drugs with these targets.