Presynaptic adenosine A2A receptors dampen cannabinoid CB1 receptor-mediated inhibition of corticostriatal glutamatergic transmission.

BACKGROUND AND PURPOSE: Both cannabinoid CB1 and adenosine A2A receptors (CB1 receptors and A2A receptors) control synaptic transmission at corticostriatal synapses, with great therapeutic importance for neurological and psychiatric disorders. A postsynaptic CB1 -A2A receptor interaction has already been elucidated, but the presynaptic A2A receptor-mediated control of presynaptic neuromodulation by CB1 receptors remains to be defined. Because the corticostriatal terminals provide the major input to the basal ganglia, understanding the interactive nature of converging neuromodulation on them will provide us with novel powerful tools to understand the physiology of corticostriatal synaptic transmission and interpret changes associated with pathological conditions. EXPERIMENTAL APPROACH: Pharmacological manipulation of CB1 and A2A receptors was carried out in brain nerve terminals isolated from rats and mice, using flow synaptometry, immunoprecipitation, radioligand binding, ATP and glutamate release measurement. Whole-cell patch-clamp recordings were made in horizontal corticostriatal slices. KEY RESULTS: Flow synaptometry showed that A2A receptors were extensively co-localized with CB1 receptor-immunopositive corticostriatal terminals and A2A receptors co-immunoprecipitated CB1 receptors in these purified terminals. A2A receptor activation decreased CB1 receptor radioligand binding and decreased the CB1 receptor-mediated inhibition of high-K(+) -evoked glutamate release in corticostriatal terminals. Accordingly, A2A receptor activation prevented CB1 receptor-mediated paired-pulse facilitation and attenuated the CB1 receptor-mediated inhibition of synaptic transmission in glutamatergic synapses of corticostriatal slices. CONCLUSIONS AND IMPLICATIONS: Activation of presynaptic A2A receptors dampened CB1 receptor-mediated inhibition of corticostriatal terminals. This constitutes a thus far unrecognized mechanism to modulate the potent CB1 receptor-mediated presynaptic inhibition, allowing frequency-dependent enhancement of synaptic efficacy at corticostriatal synapses.

Heterogeneity of spike frequency adaptation among medium spiny neurones from the rat striatum.

The main neuronal population of the striatum is composed of the medium spiny neurones (MSNs). In fact several sub-populations of MSNs can be distinguished according to the striatal compartment (striosomes and matrix) to which they belong, their afferents and their sites of projection, their biochemical markers and their morphologies. However, these cells are generally described as an electrophysiological homogeneous population. Using brain slices from the rat and whole cell patch clamp recordings, we show that at P(15) 28% of the MSNs display a spike frequency adaptation. While the mean frequency adaptation ratio for non-adapting cells was 1.07+/-0.01 it reached 2.66+/-0.09 in adapting MSNs and the incidence of this frequency adaptation phenotype appeared to be stable during post-natal development. Single-cell RT-PCR analysis of mRNAs for mu opioid receptors, enkephalin and substance P precursors suggested that adapting MSNs are present in both striatal compartments as well as in the direct and indirect pathways of the matrix. Adapting neurones were also distinguished from non-adapting cells by a lower membrane time constant, a higher AP threshold, a reduced delay to the first spike and a higher initial firing rate. Micro-domains differing by their magnitude of adaptation could be distinguished within the spike frequency adaptation process.A subgroup of MSNs exists, showing a marked spike frequency adaptation together with other distinct properties, such as shorter delay to first spike and membrane time constant, and higher initial frequency and action potential threshold. In conclusion, when strong cortical inputs are delivered in coincidence, adapting MSNs could not only transmit faster the first AP but also exert a sort of cutoff of the transmission due to their spike frequency adaptation process.

ATP-induced inhibition of gap junctional communication is enhanced by interleukin-1 beta treatment in cultured astrocytes.

Nucleotides are signaling molecules involved in variety of interactions between neurons, between glial cells as well as between neurons and glial cells. In addition, ATP and other nucleotides are massively released following brain insults, including inflammation, and may thereby be involved in mechanisms of cerebral injury. Recent concepts have shown that in astrocytes intercellular communication through gap junctions may play an important role in neuroprotection. Therefore, we have studied the effects of nucleotides on gap junction communication in astrocytes. Based on measurement of intercellular dye coupling and recording of junctional currents, the present study shows that ATP (10-100 microM) induces a rapid and a concentration-dependent inhibition of gap junction communication in cultured cortical astrocytes from newborn mice. Effects of agonists and antagonists of purinergic receptors indicate that the inhibition of gap junctional communication by ATP mainly involves the stimulation of metabotropic purinergic 1 (P2Y(1)) receptors. Pretreatment with the pro-inflammatory cytokine interleukin-1beta (10 ng/ml, 24 h), which has no effect by itself on gap junctional communication, increases the inhibitory effect of ATP and astrocytes become sensitive to uridine 5'-triphosphate (UTP). As indicated by the enhanced expression of P2Y(2) receptor mRNA, P2Y(2) receptors are responsible for the increased responses evoked by ATP and UTP in interleukin-1beta-treated cells. In addition, the effect of endothelin-1, a well-known inhibitor of gap junctional communication in astrocytes was also exacerbated following interleukin-1beta treatment. We conclude that ATP decreases intercellular communication through gap junctions in astrocytes and that the increased sensitivity of gap junction channels to nucleotides and endothelin-1 is a characteristic feature of astrocytes exposed to pro-inflammatory treatments.

Preservation of the hyperdirect pathway of basal ganglia in a rodent brain slice.

Basal ganglia are a network of interconnected nuclei, involved in motor control, goal-directed behaviors and procedural learning. Basal ganglia process information from the cerebral cortex through three main pathways. The striatum is the input nucleus of the direct (cortico-striato-nigral) and indirect (cortico-striato-pallido-subthalamo-nigral) pathways while the subthalamic nucleus (STN) is the input structure of the hyperdirect (cortico-subthalamo-nigral) pathway. Despite the fact that the hyperdirect pathway constitutes a central part of most of basal ganglia models, experimental studies concerning its synaptic transmission and plasticity are still lacking. This is mainly because in vitro brain slices do not preserve the hyperdirect pathway. Here, we address this by developing a hyperdirect pathway brain slice where cortico-subthalamo-nigral connections were preserved. We characterized the transmission properties and its monosynaptic features between the frontal cortex and the STN, and between the STN and the substantia nigra pars reticulata (SNr), the output nucleus of the hyperdirect pathway. Cortical stimulation evoked monosynaptic glutamatergic events in STN neurons with a mean latency of 11.3 ms and a mean amplitude of 21 pA. STN stimulations evoked monosynaptic glutamatergic events in SNr neurons with a mean latency of 2.5 ms and a mean amplitude of 116 pA. This brain slice also preserved a part of the direct and indirect pathways such as the cortico-striatal connection. This novel slice configuration containing the hyperdirect pathway is a useful tool to better understand the transmission and plasticity in this pathway and hence the physiology and the pathophysiology of basal ganglia.

Spike frequency adaptation is developmentally regulated in substantia nigra pars compacta dopaminergic neurons.

Dopaminergic neurons of the substantia nigra pars compacta play a key role in the modulation of basal ganglia and provide a reward-related teaching signal essential for adaptative motor control. They are generally considered as a homogenous population despite several chemical and electrophysiological heterogeneities, which could underlie different preferential patterns of activity and/or different roles. Using whole-cell patch-clamp recordings in juvenile rat brain slices, we observed that the evoked activity of dopaminergic neurons displays variable spike frequency adaptation patterns. The intensity of spike frequency adaptation decreased during post-natal development. The adaptation was associated with an increase in the initial firing frequency due to faster kinetics of the afterhyperpolarization component of the spike. Adaptation was enhanced when small conductance calcium-activated potassium (SK) channels were blocked with bath application of apamine. Lastly, spike frequency adaptation of the evoked discharge was associated with more irregularity in the spontaneous firing pattern. Altogether these results show a developmental heterogeneity and electrophysiological maturation of substantia nigra dopaminergic neurons.

Asymmetric spike-timing dependent plasticity of striatal nitric oxide-synthase interneurons.

Corticostriatal projections constitute the major inputs to basal ganglia, an ensemble of sub-cortical nuclei involved in the learning of cognitive-motor sequences in response to environmental stimuli. Besides striatal output neurons (medium-sized spiny neurons, MSNs) in charge of the detection of cortical activity, three main classes of interneurons (GABAergic, cholinergic and nitric oxide (NO)-synthase interneurons) tightly regulate the corticostriatal information transfer. Despite the crucial role of NO on neuronal signaling and synaptic plasticity, little is known about corticostriatal synaptic transmission and plasticity at the level of striatal neuronal nitric oxide synthase (nNOS) interneurons. Using a corticostriatal rat brain slice preserving the connections between the somatosensory cortex and the striatal cells, we have explored the synaptic transmission between the cerebral cortex and striatal nNOS interneurons and their capability to develop activity-dependent long-term plasticity based on the quasi-coincident cortical and striatal activities (spike-timing dependent plasticity, STDP). We have observed that cortical pyramidal cells activate monosynaptically and very efficiently the striatal nNOS interneurons. In addition, nNOS interneurons are able to develop strong bidirectional long-term plasticity, following STDP protocols. Indeed, the strength of cortically-evoked response at nNOS interneurons varied as a function of time interval between pre- and postsynaptic activations (Deltat=t(post)-t(pre)). For Deltat<0, excitatory post-synaptic currents (EPSCs) were depressed, peaking at a delay of -25 ms. For Deltat>0, EPSCs depressed for 00 and long-term potentiation (LTP) induced by "late" Deltat>0.

Gap junctions in brain glial cells and development.

In mammalian brain, glia are likely the most abundant and widespread cell population connected by gap junctions. Here, we summarize recent findings concerning the distribution, expression, and regulation of gap junction proteins in different glial subtypes and their possible roles in modulating the function of the nervous system. Intercellular communication through gap junctions is proposed to be one of the required interactions between cells during development, and we discuss how gap junctions could participate in development of brain glial cells.

Intercellular calcium signaling and gap junctional communication in astrocytes.

Two main characteristics of astrocytes are their elaborated intracellular calcium signaling and their high degree of intercellular communication mediated by gap junctional channels. In these cells a number of studies have contributed to demonstrate that the combination of these two properties provides a basis for a long-range signaling system within the brain. Intercellular calcium signaling, also termed calcium waves, allows astrocytes to communicate with each other and to interact with adjacent neurons. Most of the intra- and inter-cellular events involved in the initiation and propagation phases of this process has now been identified. This sequence of events includes the permeability of gap junction channels, which at the time-scale for calcium waves propagation, are likely permeated rather than closed by Ca2+ and/or related signaling molecules like IP3. In addition, in some studies an external component have been reported to participate to the propagation process. Finally, the control of the spread of intercellular calcium signaling has been demonstrated to occur at several levels including phospholipase C, IP3 receptors, intracellular Ca2+ stores, and cytoplasmic Ca2+ buffering. Accordingly, normal and pathological situations that affect one or several of these steps can be predicted to influence on astrocytic calcium waves.

(R)-methanandamide inhibits receptor-induced calcium responses by depleting internal calcium stores in cultured astrocytes.

The effect of (R)-methandamide, a chiral analog of the endogenous cannabimimetic anandamide, was investigated on calcium signalling in cultured rat astrocytes loaded with Indo-1. Pretreatment of astrocytes with (R)-methandamide resulted in the inhibition of calcium responses induced by endothelin-1 or glutamate. Test of the filling level of internal calcium stores and biochemical assays of phospholipase C activity suggested that this inhibition resulted from the depletion of internal pools. This effect occurred in a reversible time- and dose-dependent manner, and was prevented by treating the cells with pertussis toxin (PTX) but was not reproduced by similar concentrations of arachidonic acid. Altogether, these observations demonstrate that this stable analog of anandamide controls calcium signalling in astrocytes through a PTX-sensitive mechanism which leads to the depletion of fast mobilizable internal stores.

Mechanism involved in initiation and propagation of receptor-induced intercellular calcium signaling in cultured rat astrocytes.

The mechanisms involved in the initiation and the propagation of intercellular calcium signaling (calcium waves) were studied in cultured rat astrocytes. The analysis of calcium waves, induced either by mechanical stimulation or by focal application of ionomycin, indicated that initiation was dependent on the presence of external calcium. In addition, pharmacological experiments indicate that intercellular propagation required PLC activation, integrity of IP3-sensitive internal calcium stores, and functional gap junctions. An extracellular action of ATP or glutamate and participation of voltage-dependent Ca2+ channels were tested by using enzymatic degradation, receptor antagonists, and channel blockers, respectively. Because neither the speed of propagation nor the extent of the calcium waves was affected by these treatments, these alternate mechanisms were excluded from playing a role in intercellular calcium signaling. Biochemical assays and focal applications of several agonists (methoxamine, carbachol, glutamate) of membrane receptors to neurotransmitters and peptides (endothelin 1) demonstrated that their ability to trigger regenerative calcium waves depended on phospholipase C activity and inositol phosphate production. Thus, in rat astrocytes, initiation and propagation of calcium waves involve a sequence of intra- and intercellular steps in which phospholipase C, inositol trisphosphate, internal calcium stores, and gap junction channels play a critical role. The identification of these different events allows us to determine several targets at which the level of long-range signaling in astrocytes may be controlled.

Inhibition by anandamide of gap junctions and intercellular calcium signalling in striatal astrocytes.

Anandamide, an endogenous arachidonic acid derivative that is released from neurons and activates cannabinoid receptors, may act as a transcellular cannabimimetic messenger in the central nervous system. The biological actions of anandamide and the identity of its target cells are, however, still poorly documented. Here we show that anandamide is a potent inhibitor of gap-junction conductance and dye permeability in striatal astrocytes. This inhibitory effect is specific for anandamide as compared to co-released congeners or structural analogues, is sensitive to pertussis toxin and to protein-alkylating agents, and is neither mimicked by cannabinoid-receptor agonists nor prevented by a cannabinoid-receptor antagonist. Glutamate released from neurons evokes calcium waves in astrocytes that propagate via gap junctions, and may, in turn, activate neurons distant from their initiation sites in astrocytes. We find that anandamide blocks the propagation of astrocyte calcium waves generated by either mechanical stimulation or local glutamate application. Thus, by regulating gap-junction permeability, anandamide may control intercellular communication in astrocytes and therefore neuron-glial interactions.

Gap junctional communication and pharmacological heterogeneity in astrocytes cultured from the rat striatum.

Indo-1 and fluo-3 imaging techniques were used to investigate the role of gap junctions in the changes in cytosolic calcium concentrations ([Ca2+]i) induced by several receptor agonists. Subpopulations of confluent cultured astrocytes from the rat striatum were superfused with submaximal concentrations of endothelin-1 (Et1) and the alpha 1-adrenergic and muscarinic receptor agonists, methoxamine and carbachol, respectively. 2. Combined binding and autoradiographic studies indicated that all striatal astrocytes possess binding sites for Et1. In contrast, alpha 1-adrenergic and muscarinic binding sites were found to be heterogeneously distributed. In agreement with these findings, Et1 induced fast calcium responses in all cells while only subsets of striatal astrocytes responded to the application of methoxamine or carbachol. 3. Halothane, heptanol and octanol, which are commonly used as gap junction inhibitors, drastically reduced the amplitude of Et1-induced calcium responses. In contrast, 18-alpha-glycyrrhetinic acid (alpha GA) used at a concentration known to block gap junction permeability in astrocytes had no significant effect on the amplitude of these calcium responses. 4. As demonstrated by quantitative and topological analysis, Et1 application similarly increased [Ca2+]i levels in all astrocytes in both the absence and presence of alpha GA. 5. In control conditions, subpopulations of cells responding to methoxamine or carbachol exhibited two main types of calcium responses which differed in their shape and kinetic characteristics. In the presence of alpha GA the number of cells responding to these receptor agonists was significantly reduced. Indeed, responses characterized by their long latency, slow rise time and weak amplitude disappeared in the presence of alpha GA while responses with short latency and fast rise time were preserved. 6. These results indicate that permeable gap junction channels tend to attenuate the pharmacological and functional heterogeneity of populations of astrocytes, while their inhibition restricts calcium responses in astrocytes expressing high densities of transmitter receptors coupled to phospholipase C.

Gap junctions and connexin expression in the normal and pathological central nervous system.

Gap junctions are widely expressed in the various cell types of the central nervous system. These specialized membrane intercellular junctions provide the morphological support for direct electrical and biochemical communication between adjacent cells. This intercellular coupling is controlled by neurotransmitters and other endogenous compounds produced and released in basal as well as in pathological situations. Changes in the expression and the function of connexins are associated with number of brain pathologies and lesions suggesting that they could contribute to the expansion of brain damages. The purpose of this review is to summarize data presently available concerning gap junctions and the expression and function of connexins in different cell types of the central nervous system and to present their physiopathological relevance in three major brain dysfunctions: inflammation, epilepsy and ischemia.

Connexin expression in electrically coupled postnatal rat brain neurons.

Electrical coupling by gap junctions is an important form of cell-to-cell communication in early brain development. Whereas glial cells remain electrically coupled at postnatal stages, adult vertebrate neurons were thought to communicate mainly via chemical synapses. There is now accumulating evidence that in certain neuronal cell populations the capacity for electrical signaling by gap junction channels is still present in the adult. Here we identified electrically coupled pairs of neurons between postnatal days 12 and 18 in rat visual cortex, somatosensory cortex, and hippocampus. Notably, coupling was found both between pairs of inhibitory neurons and between inhibitory and excitatory neurons. Molecular analysis by single-cell reverse transcription-PCR revealed a differential expression pattern of connexins in these identified neurons.

Biosynthesis of an endogenous cannabinoid precursor in neurons and its control by calcium and cAMP.

Understanding the mechanisms involved in the biogenesis of N-arachidonoylethanolamine (anandamide) and N-palmitoylethanolamine is important in view of the possible role of these lipids as endogenous cannabinoid substances. Anandamide (which activates cannabinoid CB1 receptors) and N-palmitoylethanolamine (which activates a CB2-like receptor subtype in mast cells) may both derive from cleavage of precursor phospholipid, N-acylphosphatidylethanolamine (NAPE), catalyzed by Ca(2+)-activated D-type phosphodiesterase activity. We report here that the de novo biosynthesis of NAPE is enhanced in a Ca(2+)-dependent manner when rat cortical neurons are stimulated with the Ca(2+)-ionophore ionomycin or with membrane-depolarizing agents such as veratridine and kainate. This reaction is likely to be mediated by a neuronal N-acyltransferase activity, which catalyzes the transfer of an acyl group from phosphatidylcholine to the ethanolamine moiety of phosphatidylethanolamine. In addition, we show that Ca2+-dependent NAPE biosynthesis is potentiated by agents that increase cAMP levels, including forskolin and vasoactive intestinal peptide. Our results thus indicate that NAPE levels in cortical neurons are controlled by Ca2+ ions and cAMP. Such regulatory effect may participate in maintaining a supply of cannabimimetic N-acylethanolamines during synaptic activity, and prime target neurons for release of these bioactive lipids.

Homotypic and heterotypic coupling mediated by gap junctions during glial cell differentiation in vitro.

Intercellular communication mediated by gap junctions was investigated during oligodendrocyte differentiation in primary and secondary cell cultures from newborn and adult rats. Two types of communication were considered: ionic coupling and dye-coupling between similar oligodendrocytes selected at the same stage of differentiation (homotypic) and dye-coupling between oligodendrocytes and astrocytes (heterotypic). Intercellular diffusion of fluorescent probes and double whole-cell recordings were used to test the incidence of dye and ionic communication respectively. Progenitor cells, identified with A2B5 antibodies, were characterized by the absence of ionic and dye-coupling, whereas oligodendrocytes, identified with galactosylceramide antibodies, exhibited both types of communication. This homotypic coupling was inhibited by various uncoupling agents, but unaffected by treatments which increased the intracellular concentration of cAMP. In cocultures of astrocytes and oligodendrocytes, Lucifer yellow and sulphorhodamine B were exchanged in both directions. This heterotypic dye-coupling, which could be blocked by octanol, first appeared after 3 weeks in culture and increased to an incidence of 25% after 6 weeks, a developmental pattern comparable to homotypic dye-coupling between oligodendrocytes. In contrast, during the same period, progenitors and microglia were never observed to be dye-coupled with astrocytes.

Anandamide and WIN 55212-2 inhibit cyclic AMP formation through G-protein-coupled receptors distinct from CB1 cannabinoid receptors in cultured astrocytes.

The effects of anandamide and the cannabinoid receptor agonists WIN 55212-2 and CP 55940 on the evoked formation of cyclic AMP were compared in cultured neurons and astrocytes from the cerebral cortex and striatum of mouse embryos. The three compounds inhibited the isoproterenol-induced accumulation of cyclic AMP in neuronal cells, and these responses were blocked by the selective CB1 receptor antagonist SR 141716A. The three agonists were more potent in cortical than striatal neurons. Interestingly, WIN 55212-2, CP 55940 and anandamide also inhibited the isoproterenol-evoked accumulation of cyclic AMP in astrocytes but, in contrast to WIN 55212-2 and CP 55940, anandamide was much more potent in striatal than cortical astrocytes. Inhibition was prevented by pertussis toxin pretreatment, but not blocked by SR 141716A. Therefore, G-protein-coupled receptors, distinct from CB1 receptors, are involved in these astrocytic responses. Moreover, specific binding sites for [3H]-SR 141716A were found in neurons but not astrocytes. Furthermore, using a polyclonal CB1 receptor antibody, staining was observed in striatal and cortical neurons, but not in striatal and cortical astrocytes. Taken together, these results suggest that glial cells possess G-protein-coupled receptors activated by cannabinoids distinct from the neuronal CB1 receptor, and that glial cells responses must be taken into account when assessing central effects of cannabinoids.

Endothelins regulate astrocyte gap junctions in rat hippocampal slices.

Gap junctional communication (GJC) is a typical feature of astrocytes proposed to contribute to the role played by these glial cells in brain physiology and pathology. In acutely isolated hippocampal slices from rat (P11-P19), intercellular diffusion of biocytin through gap junction channels was shown to occur between hundreds of cells immuno-positive for astrocytic markers studied in the CA1/CA2 region. Single-cell RT-PCR demonstrated astrocytic mRNA expression of several connexin (Cx) subtypes, the molecular constituent of gap junction channels, whereas immunoblotting confirmed that Cx43 and Cx30 are the main gap junction proteins in hippocampal astrocytes. In the brain, astrocytes represent a major target for endothelins (Ets), a vasoactive family of peptides. Our results demonstrate that Ets decrease the expression of phosphorylated Cx43 forms and are potent inhibitors of GJC. The Et-induced effects were investigated using specific Et receptor agonists and antagonists, including Bosentan (Tracleer trade mark ), an EtA/B receptor antagonist, and using hippocampal slices and cultures from EtB-receptor-deficient rats. Interestingly, the pharmacological profile of Ets effects did not follow the classical profile established in cardiovascular systems. The present study therefore identifies Ets as potent endogenous inhibitory regulators of astrocyte networks. As such, the action of these peptides on astrocyte GJC might be involved in the contribution of astrocytes to neuroprotective processes and have a therapeutic potential in neuropathological situations.