Peripheral administration of group III mGlu receptor agonist ACPT-I exerts potential antipsychotic effects in rodents.

Several lines of evidence implicate dysfunction of glutamatergic neurotransmission in the pathophysiology of schizophrenia. Previous behavioral studies have indicated that metabotropic glutamate (mGlu) receptors may be useful targets for the treatment of psychosis. It has been shown that agonists and positive allosteric modulators of group II mGlu receptors produce potential antipsychotic effects in behavioral models of schizophrenia in rodents. Group III mGlu receptors seem to be also promising targets for a variety of neuropsychiatric and neurodegenerative disorders. However, despite encouraging data in animal models, most ligands of group III mGlu receptors still suffer from weak affinities, incapacity to cross the blood-brain barrier or absence of full pharmacological characterization. These limitations slow down the validation process of group III mGlu receptors as therapeutic targets. In this work, we choose to study an agonist of group III mGlu receptors (1S,3R,4S)-1-aminocyclo-pentane-1,3,4-tricarboxylic acid (ACPT-I) using intraperitoneal administration in three animal behavioral models predictive of psychosis or hallucinations. The results of the present study show that ACPT-I, given at doses of 10 or 30mg/kg, decreased MK-801-induced hyperlocomotion and at a dose of 100mg/kg decreased amphetamine-induced hyperlocomotion in rats. Furthermore, ACPT-I dose-dependently decreased DOI-induced head twitches in mice and suppresses DOI-induced frequency and amplitude of spontaneous EPSPs in slices from mouse brain frontal cortices. These data demonstrate that ACPT-I is a brain-penetrating compound and illustrates its promising therapeutic role for the treatment of schizophrenia.

Synthesis and biological evaluation of pyrrolinic isosteres of rilmenidine. Discovery of cis-/trans-dicyclopropylmethyl-(4,5-dimethyl-4,5-dihydro-3H-pyrrol-2-yl)-amine (LNP 509), an I1 imidazoline receptor selective ligand with hypotensive activity.

To find new compounds selective for purported I1 imidazoline receptors (I1Rs) over I2 imidazoline binding sites (I2BS) and alpha2-adrenoceptors (alpha2ARs), a series of pyrrolinic isosteres of rilmenidine has been prepared and their biological activity at I1Rs, I2BS, and alpha2ARs evaluated. This isosteric replacement provided us with compounds which still bound to I1Rs but not to I2BS nor to alpha2ARs. A limited structure-affinity relationship was generated around the heterocyclic moiety of these ligands. One compound in this series, LNP 509 (1e) [cis-/trans-dicyclopropylmethyl-(4,5-dimethyl-4,5-dihydro-3H-pyrrol-2-yl)-amine], had no detectable affinity at alpha2ARs yet was capable of lowering blood pressure after central administration. These pyrrolinic analogues constitute a new chemical class of imidazoline related compounds with high selectivity for the I1Rs. They could be used as new tools in the study of I1Rs and in the conception of new centrally acting hypotensive drugs.

Respective contributions of alpha-adrenergic and non-adrenergic mechanisms in the hypotensive effect of imidazoline-like drugs.

The hypotensive effect of imidazoline-like drugs, such as clonidine, was first attributed to the exclusive stimulation of central alpha2-adrenoceptors (alpha2ARs). However, a body of evidence suggests that non-adrenergic mechanisms may also account for this hypotension. This work aims (i) to check whether imidazoline-like drugs with no alpha2-adrenergic agonist activity may alter blood pressure (BP) and (ii) to seek a possible interaction between such a drug and an alpha2ARs agonist alpha-methylnoradrenaline (alpha-MNA). We selected S23515 and S23757, two imidazoline-like drugs with negligible affinities and activities at alpha2ARs but with high affinities for non-adrenergic imidazoline binding sites (IBS). S23515 decreased BP dose-dependently (-27+/-5% maximal effect) when administered intracisternally (i.c.) to anaesthetized rabbits. The hypotension induced by S23515 (100 microg kg(-1) i.c.) was prevented by S23757 (1 mg kg(-1) i.c.) and efaroxan (10 microg kg(-1) i.c.), while these compounds, devoid of haemodynamic action by themselves, did not alter the hypotensive effect of alpha-MNA (3 and 30 microg kg(-1) i.c.). Moreover, the alpha2ARs antagonist rauwolscine (3 microg kg(-1) i.c.) did not prevent the effect of S23515. Finally, whilst 3 microg kg(-1) of S23515 or 0.5 microg kg(-1) of alpha-MNA had weak hypotensive effects, the sequential i.c. administration of these two drugs induced a marked hypotension (-23+/-2%). These results indicate that an imidazoline-like drug with no alpha2-adrenergic properties lowers BP and interacts synergistically with an alpha(ARs agonist.

I(1) imidazoline receptors involved in cardiovascular regulation: where are we and where are we going?

Clonidine-like drugs (hybrid drugs) reduce blood pressure by acting centrally at both alpha(2)-adrenergic receptors (alpha(2)AR) and I(1) receptors (I(1)R). Some attempts at cloning I(1)R have failed, probably because of the lack of selectivity of the ligands. Recently, compounds acting exclusively at I(1)R were synthesized: LNP 911, LNP509, and S23515. For example, LNP911 has a K(d) value of 1.7 nmol/L at I(1)R. LNP509 and S23515 reduce blood pressure when injected centrally in anesthetized animals, whereas S23757 behaves as an antagonist of hypotensive imidazolines. LNP509 reduces blood pressure even in genetically engineered mice lacking functional alpha(2)AR. An exclusive action at central I(1)R is therefore sufficient to modify blood pressure. With the help of drugs selective for I(1)R and alpha-methylnoradrenaline, selective for alpha(2)AR, we showed that imidazoline and alpha(2)-adrenergic mechanisms interact synergistically in controlling the blood pressure. Such a synergism may explain the very powerful hypotensive effects of hybrid drugs. The new ligands selective for I(1)R will be very helpful to investigate the molecular features and the signaling system of I(1)R.

Participation of imidazoline receptors and alpha(2-)-adrenoceptors in the central hypotensive effects of imidazoline-like drugs.

The central hypotensive effect of imidazoline-like drugs (IMs) involves non-adrenergic imidazoline receptors (IRs). IMs cause hypotension irrespective of their affinity and selectivity for one or the other alpha-adrenoceptor subtypes. LNP 509, which binds to I1Rs (Ki = 5.10(-7) M) but roughly not to alpha 2-adrenoceptors (A2Rs) (Ki > 10(-5) M), causes hypotension when injected alone into the brainstem. As far as hybrid drugs, that is, those with mixed binding profiles (I1/alpha 2), are concerned, a significant correlation was reported between their central hypotensive effect and their affinity for IRs. Imidazoline antagonists such as idazoxan competitively antagonized the centrally induced hypotensive effect of IMs. Yohimbine, an A2Rs antagonist, blocks the hypotensive effect of hybrids but usually in a noncompetitive manner. Mutation of A2Rs prevented the hypotensive effects of drugs highly selective for A2Rs, but also that of hybrids such as clonidine. These data indicate that triggering of the hypotensive effects of IMs (1) needs implication of IRs; (2) appears to be facilitated by additional activation of A2Rs; and (3) requires integrity of A2Rs along the sympathetic pathways.

The group III mGlu receptor agonist ACPT-I exerts anxiolytic-like but not antidepressant-like effects, mediated by the serotonergic and GABA-ergic systems.

Our earlier studies have demonstrated that (1S,3R,4S)-1-aminocyclo-pentane-1,3,4-tricarboxylic acid ACPT-I, a group III mGlu receptor agonist, produced anxiolytic-like and antidepressant-like actions after central administration. Here we describe the anxiolytic-like effects of ACPT-I after intraperitoneal administration in the stress-induced hyperthermia (SIH), elevated plus-maze (PMT) tests in mice and in the Vogel test in rats. However, the compound did not produce antidepressant-like effects in the tail suspension test (TST) or in the forced swim test (FST) in mice. The potential anxiolytic effect of ACPT-I (20 mg/kg) in the SIH test was inhibited by the benzodiazepine receptor antagonist flumazenil (given i.p., 10 mg/kg), and by a 5-HT(1A) receptor antagonist N-{2-[4-(2-methoxyphenyl)-1-piperazinyl]ethyl}-N-(2-pyridynyl) cyclohexane-carboxamide (WAY100635) (0.1 mg/kg s.c.). At the same time, ritanserin (0.5 mg/kg i.p.), the 5-HT2A/C receptor antagonist, did not change the anxiolytic-like effects of ACPT-I. The results of these studies indicate that the GABA-ergic and serotonergic systems are involved in the potential anxiolytic action of ACPT-I.

Imidazoline receptors: a challenge.

The hypotensive effect of imidazoline-like drugs (IMs) directly injected into the rostroventrolateral part of the brainstem (NRL/RVLM) was shown to involve non-adrenergic imidazoline specific receptors (IRs). Some IMs caused hypotension when injected there, irrespective of their affinity and selectivity for any alpha-adrenoceptor subtype. Compounds, such as LNP 509, S 23515, S 23757 or benazoline with very high selectivities for IRs over alpha 2-adrenoceptors (A2Rs), became available recently. Some of these compounds (LNP 509, S 23515) caused hypotension when injected alone into the NRL/RVLM region. Nevertheless, high selectivity for IRs will not predict by its own the capability of IMs to elicit hypotension as some of these substances behaved as antagonists towards the hypotensive effects of the latter. As far as hybrid drugs, i.e., with mixed binding profiles (I1/alpha 2), were concerned, a significant correlation has been reported between their central hypotensive effect and their affinity for IRs. Imidazoline antagonists, such as idazoxan, were repeatedly shown to competitively prevent and reverse the centrally induced hypotensive effect of IMs. The sole stimulation of A2Rs within the NRL/RVLM region was not sufficient to decrease blood pressure as much as IMs did, as shown by the lack of significant blood pressure lowering effect of alpha-methylnoradrenaline (alpha-MNA). No correlation was observed between affinity of IMs for A2Rs and their central hypotensive effects. It is also noticeable that yohimbine, an A2Rs antagonist, was repeatedly shown to abolish the hypotensive effect of hybrids but usually in a non-competitive manner. Mutation of A2Rs was shown to prevent the hypotensive effects of centrally acting drugs. It is concluded that (i) drugs highly selective for I1Rs over A2Rs can reduce blood pressure by their own; (ii) the central hypotensive effect of IMs needs implication of IRs and appears to be facilitated by additional activation of A2Rs; and (iii) this effect requires intact A2Rs along the sympathetic pathways.