A specific transduction mechanism for the glutamate action on phosphoinositide metabolism via the quisqualate metabotropic receptor in rat brain synaptoneurosomes: II. Calcium dependency, cadmium inhibition.

International audienceIn this article, we demonstrate that an increase in intracellular Ca2+ concentration may represent a specific common step(s) in the mechanism(s) of action of glutamate (Glu) and depolarizing agents on formation of inositol phosphates (IPs) in 8-day-old rat forebrain synaptoneurosomes. In fact, A23187, a Ca2+ ionophore, induces a dose-dependent accumulation of IPs, which is not additive with that evoked by Glu and K+ but is slightly synergistic with that induced by carbachol. In addition, Glu and K+ augment the intracellular Ca2+ concentration in synaptoneurosome preparations as measured by the fura-2 assay. The absence of external Ca2+ decreases basal and Glu-, and K(+)-stimulated formation of IPs. Cd2+ (100 microM) fully inhibits both Glu- and K(+)-evoked formation of IPs without affecting the carbachol-elicited response of IPs. Zn2+ inhibits Glu- and K(+)-stimulated accumulation of IPs (IC50 approximately 0.4 mM) but with a lower affinity than Cd2+ (IC50 approximately 0.035 mM). The organic Ca2+ channel blockers verapamil (10 microM), nifedipine (10 microM), omega-conotoxin (2 microM), and amiloride (10 microM) as well as the inorganic blockers Co2+ (100 microM) and La3+ (100 microM) block neither Glu- nor K(+)-evoked formation of IPs, a result suggesting that the opening of the L-, T-, N-, or P-type Ca2+ channels does not participate in these responses. All these data suggest that an increase in intracellular Ca2+ concentration resulting from an influx of Ca2+, sensitive to Cd2+ but not to other classical Ca2+ antagonists, may play a key role in the transduction mechanism activated by Glu or depolarizing agents

The putative molecular mechanism(s) responsible for the enhanced inositol phosphate synthesis by excitatory amino acids: an overview.

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DNQX-induced toxicity in cultured rat hippocampal neurons: an apparent AMPA receptor-independent effect?

International audienceTo evaluate the involvement of AMPA receptor activation in neuronal cell death and survival, rat hippocampal neurons in culture were treated with AMPA receptor antagonists. A 46 h treatment with 6,7-dinitroquinoxaline-2,3-dione (DNQX), added 2 h after cell plating, induces a dose-dependent neurotoxicity. Similar effects are also observed in more mature hippocampal neurons (treatment at 14 days in vitro). DNQX toxic effect is neuron-specific since cultured hippocampal glial cells are unaffected. Attempts to characterise the site of action of DNQX suggest that ionotropic glutamate receptors would not be implicated. Indeed, (i) other AMPA receptor antagonists are either ineffective or only moderately efficient in mimicking DNQX effects; (ii) AMPA alone or in the presence of cyclothiazide, as well as, other AMPA receptor agonists, do not reverse DNQX action; (iii) DNQX neurotoxicity is not likely to involve blockade of NMDA receptor glycine site, since this effect is neither mimicked by 7-chlorokynurenate nor reversed by D-serine. Thus, DNQX toxicity in cultured hippocampal neurons is apparently mediated through an ionotropic glutamate receptor-independent way

Astrocytes repress the neuronal expression of GLAST and GLT glutamate transporters in cultured hippocampal neurons from embryonic rats.

International audienceGlutamate extracellular levels are regulated by specific transporters. Five subtypes have been identified. The two major ones, GLAST and GLT (glutamate transporters 1 and 2, respectively), are localized in astroglia in normal mature brain. However, in neuron-enriched hippocampal cultures, these proteins are expressed in neurons during the early in vitro development (Plachez et al., 2000). Here, we show that, in these cultures, GLAST and GLT neuronal expression is transient and no longer observed after 7 days in vitro, a stage at which the few astrocytes present in the culture are maturing. Moreover, we demonstrate that these few astrocytes are responsible for the repression of this neuronal expression. Indeed, addition of conditioned medium prepared from primary cultures of hippocampal astrocytes, to cultured hippocampal neurons, rapidly leads to the suppression of neuronal GLAST expression, without affecting neuronal GLT expression. However, when neurons are seeded and co-cultured on a layer of hippocampal astrocytes, they do not develop any immunoreactivity towards GLAST or GLT antibodies. Altogether, these results indicate that glia modulate the expression of GLAST and GLT glutamate transporters in neurons, via at least two distinct mechanisms. Neuronal GLAST expression is likely repressed via the release or the uptake of soluble factors by glia. The repression of neuronal GLT expression probably results from glia-neuron interactions. This further reinforces the fundamental role of direct or indirect neuron-glia interactions in the development of the central nervous system

Effect of thiol reagents on phosphoinositide hydrolysis in rat brain synaptoneurosomes.

International audienceSome divalent ions, such as Cd2+ and Zn2+, are able to stimulate phosphoinositide (PI) breakdown and to inhibit receptor-mediated PI metabolism. These ions are also known to react with the free -SH groups of proteins. This prompted us to investigate the effects of more potent sulphydryl reagents, Hg2+ and p-chloromercuric benzosulphonic acid (PCMBS), on the inositol phosphate (IP) accumulation triggered by the neuroactive substances: glutamate, carbachol and K+, using synaptoneurosomes from 8-day-old rat forebrains. Hg2+ and PCMBS, depending on their concentration, had two distinct effects on IP accumulation: at low doses, Hg2+ (from 1 to 10 microM) and PCMBS (0.1 mM) by themselves stimulated PI breakdown, inhibited glutamate-elicited IP accumulation and had additive effects with respect to carbachol-induced IP stimulation. At higher doses, Hg2+ (from 0.01 to 1 mM) inhibited both basal and neuroactive substance-stimulated IP accumulation. PCMBS (1 mM), provoked only an inhibition of the agonist-stimulated IP formation. Monitoring membrane potential and intracellular Ca2+ with the fluorescent dyes diSC2(5) and fura2, respectively, indicated that these mercurials could strongly depolarize the synaptoneurosomal membrane and produce a Ca2+ influx dependent on extracellular Ca2+. The stimulatory effects of low concentrations of mercurials on PI turnover could be linked to the depolarization they provoke and the subsequent Ca2+ rise, which in turn is known to stimulate some phospholipase C enzymes. The inhibitory effects observed at high concentrations might be due to a loss of activity of proteins involved in PI breakdown, as all receptor-mediated IP accumulations were inhibited

Ototoxic and nephrotoxic drugs inhibit agonist-induced inositol phosphate formation in rat brain synaptoneurosomes.

International audienceNeomycin (an aminoglycoside antibiotic), ethacrynate (a loop diuretic), cisplatin (an anticancer drug) and mercuric chloride are chemically unrelated drugs which present similar ototoxic and nephrotoxic properties. We have found that all these molecules inhibit inositol phosphate turnover induced by carbachol or glutamate in rat brain synaptoneurosomes. Since this second messenger system appears to be a key mechanism for cell functioning and even survival, our observations raise the possibility that the expression of the specific toxicity of these compounds may result from excessive inhibition of the phosphoinositide cascade

Metabotropic glutamate receptors as drug targets.

International audienceL-glutamate (Glu), the main excitatory amino acid neurotransmitter in the mammalian central nervous system, is involved in many physiological functions, including learning and memory, but also in toxic phenomena occurring in numerous degenerative or neurological diseases. These functions mainly result from its interaction with Glu receptors (GluRs). The broad spectrum of roles played by glutamate derived from the large number of membrane receptors, which are currently classified in two main categories, ionotropic (iGluRs) and metabotropic (mGluRs) receptors. The iGluRs are ion channels, permeant to Na(+) (Ca(2+)) while the mGluRs belongs to the superfamily of G-protein coupled receptors (GPCRs). Despite continuous efforts over more than two decades, the use of iGluR agonists or antagonists to improve or inhibit excitatory transmission in pathological states still remains a major challenge, though the discovery and development of recent molecules may prove it worthwhile. This probably results form the vital role of fast excitatory transmission in many fundamental physiological functions. Since the discovery of mGluRs, hope has emerged. Indeed, mGluRs are mainly involved in the regulation of fast excitatory transmission. Consequently, it was logically thought that modulating mGluRs with agonists or antagonists might lead to more subtle regulation of fast excitatory transmission than by directly blocking iGluRs. As a result of intensive investigation, new drugs permitting to discriminate between these receptors have emerged. Moreover, a new class of molecules acting as negative or positive allosteric modulators or mGluRs is now available and appears to be promising. In the following, we will review the classification of mGluRs and the functions in which mGluRs are involved. We will focus on their potential as therapeutic targets for improving numerous physiological functions and for different neurodegenerative and neuropsychiatric disorders, which are related to malfunction of Glu signaling in human beings

A new quisqualate receptor subtype (sAA(2)) responsible for the glutamate-induced inositol phosphate formation in rat brain synaptoneurosomes.

International audienceInositol phosphate synthesis elicited by excitatory amino acids was measured in rat forebrain synaptoneurosomes in presence of Li(+). Quisqualate (QA) was the most potent excitatory amino acid inducing inositol phosphate formation. This QA action was not blocked by any of the usual antagonists [glutamate-amino-methyl-sulphonate (GAMS); glutamate-diethyl-ester (GDEE); ?-d-glutamyl-glycine (?-DGG)] known to inhibit the QA-induced depolarization. The same was found for the most potent and selective QA antagonist reported so far [6-nitro-7-cyanoquinoxaline-2,3-dion (FG 9065)]. In addition, dl-?-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) a potent depolarizing agonist at the quisqualate receptor subtype was about 300 times less potent than quisqualate in increasing inositol phosphate accumulation. Our results provide the first pharmacological evidence indicating that a new quisqualate receptor subtype, tentatively termed sAA(2) is responsible for inositol phosphate formation

Cadmium rapidly and irreversibly blocks presynaptic phospholipase C-linked metabotropic glutamate receptors.

International audienceCalcium ions (Cd2+) inhibit inositol phosphate (IP) formation elicited by glutamate (GLU) or K+ ions, without affecting carbachol (Carb)-induced IP response in 8-day-old rat forebrain synaptoneurosomes and synaptosomes. On the contrary, Cd2+ was almost ineffective in blocking GLU- and K(+)-responses in hippocampal neurones in culture. The mechanism of Cd2+ inhibition was thus examined in synaptoneurosomes. Extensive washing of synaptoneurosomes pretreated for 1, 5, 15, or 30 min by 100 microM Cd2+ did not modify the inhibitory effect of Cd2+ on GLU-, K(+)- and A23187-evoked IP formation or its lack of effect on Carb response. The later addition of a high affinity Cd2+ chelator (100 microM), N,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine (TPEN) also did not reverse the inhibitory effect. TPEN, however, penetrates into synaptoneurosomes and efficiently displaces Cd2+ from the Fura-2-Cd2+ complex as shown by Fura-2 fluorescence recordings. TPEN is not easily removed from the intracellular space, as demonstrated by its ability to still block Cd(2+)-induced Fura-2 fluorescence increase after extensive washing. Pretreatment of synaptoneurosomes by this chelator did not prevent Cd2+ inhibition of GLU-induced IP formation. These data indicate that Cd2+ ions rapidly, irreversibly and extracellularly inhibit GLU-elicited IP formation in synaptoneurosomes or synaptosomes, but not in hippocampal neurones in culture. It is speculated that Cd2+ ions could allow one to distinguish the activity of presynaptic metabotropic glutamate receptors (mGLURs) linked to phosphoinositide metabolism from that of mGLURs located postsynaptically

Carbachol-induced inositol phosphate formation during rat cochlea development.

International audienceThe age related-intensity developmental pattern of the phosphoinositide breakdown, which leads to the formation of intracellular second messengers, was investigated in rat cochleas by measuring the accumulation of inositol phosphates induced by carbachol in the presence of LiCl. The accumulation of the phosphoinositide metabolites elicited by this muscarinic agonist is very low at post-natal day 1 and particularly large during the period between post-natal days 8 and 14 with a peak around day 12. In the 25-day-old rat cochlea, carbachol induced a 2-fold increase in inositol phosphates (IPs) accumulation, with respect to the basal control level. The apparent affinities of the carbachol-induced IPs responses are 49.6, 31.6 and 36.7 microM in cochleas of 12-, 16- and 25-day-old rats, respectively, thus suggesting that the specific developmental changes are rather due to a modification in the number of muscarinic cholinergic receptors than to alterations of the apparent affinity of carbachol for its receptors. This developmental pattern of carbachol-elicited IPs accumulation reveals a striking time coincidence with both the efferent synaptogenesis at the outer hair cells (OHCs) level and the period of increased sensitivity of OHCs to aminoglycoside toxicity. Phosphoinositide breakdown may, consequently, play a role in the maturation of OHCs and their efferent supply. In addition, the remaining IPs response measured at 25 post-natal days indicates that muscarinic agonist-mediated IPs metabolism also occurs in mature cochlea, and might be involved in the regulation of OHCs motility