Calcium signals in the nucleus accumbens: Activation of astrocytes by ATP and succinate

Molnár, Tünde; Dobolyi, Árpád; Nyitrai, Gabriella; Barabás, Péter; Héja, László; Emri, Zsuzsa; Palkovits, Miklós; Kardos, Julianna

doi:10.1186/1471-2202-12-96

Cited by 24 publications

(38 citation statements)

References 74 publications

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“…Since inhibition of neuronal Cx36 may also result in reduced synchronization 42 , we opted to specifically block the astrocytic Cx43 isoform with a specific antibody against its gating peptide segment 43 , which has previously been demonstrated to inhibit Cx43 function 16, 39 . The Cx43 antibody (0.75 mg/ml, 10 μl) was applied to the cortical surface 24 hours before the experiment to ensure antibody penetration into layer 2.…”

Section: Resultsmentioning

confidence: 99%

Extensive astrocyte synchronization advances neuronal coupling in slow wave activity in vivo

Szabó

Héja

Szalay

et al. 2017

Sci Rep

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Slow wave activity (SWA) is a characteristic brain oscillation in sleep and quiet wakefulness. Although the cell types contributing to SWA genesis are not yet identified, the principal role of neurons in the emergence of this essential cognitive mechanism has not been questioned. To address the possibility of astrocytic involvement in SWA, we used a transgenic rat line expressing a calcium sensitive fluorescent protein in both astrocytes and interneurons and simultaneously imaged astrocytic and neuronal activity in vivo. Here we demonstrate, for the first time, that the astrocyte network display synchronized recurrent activity in vivo coupled to UP states measured by field recording and neuronal calcium imaging. Furthermore, we present evidence that extensive synchronization of the astrocytic network precedes the spatial build-up of neuronal synchronization. The earlier extensive recruitment of astrocytes in the synchronized activity is reinforced by the observation that neurons surrounded by active astrocytes are more likely to join SWA, suggesting causality. Further supporting this notion, we demonstrate that blockade of astrocytic gap junctional communication or inhibition of astrocytic Ca2+ transients reduces the ratio of both astrocytes and neurons involved in SWA. These in vivo findings conclusively suggest a causal role of the astrocytic syncytium in SWA generation.

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Section: Resultsmentioning

confidence: 99%

Extensive astrocyte synchronization advances neuronal coupling in slow wave activity in vivo

Szabó

Héja

Szalay

et al. 2017

Sci Rep

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“…Activation of the presumed brain type SUC receptor (as an analogy to SUCNR1 we reference this putative receptor as SUCBR1) by agonists SUC or GHB evokes repetitive Ca 2+ transients in astrocytes independently of neuronal signaling (Molnár et al, 2009, 2011). A sub-population of SUCBR1-triggered repetitive Ca 2+ transients can also be activated by ATP making Ca 2+ signaling more robust.…”

Section: Discussionmentioning

confidence: 99%

“…We also observed for the first time the activation of repetitive astroglial Ca 2+ transients in response to the major intermediate of the citric acids cycle succinic acid (SUC). The apparent EC 50 (50–60 μM) of SUC effect is within the range of physiological plasma SUC concentration (Molnár et al, 2011), since the concentration of SUC in plasma increases from 5 up to 125 μM with exercise, metabolic acidosis or hyperglycemic metabolic states (Krebs, 1950; Nordmann and Nordmann, 1961; Hochachka and Dressendorfer, 1976; Kushnir et al, 2001; Forni et al, 2005; Sadagopan et al, 2007). These data suggest that SUC-responsive Ca 2+ transients may also have a regulatory role for cellular energy supply.…”

Section: Introductionmentioning

confidence: 97%

Activation of astroglial calcium signaling by endogenous metabolites succinate and gamma-hydroxybutyrate in the nucleus accumbens

et al. 2011

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Accumulating evidence suggests that different energy metabolites play a role not only in neuronal but also in glial signaling. Recently, astroglial Ca2+ transients evoked by the major citric acid cycle metabolite succinate (SUC) and gamma-hydroxybutyrate (GHB) that enters the citric acid cycle via SUC have been described in the brain reward area, the nucleus accumbens (NAc). Cells responding to SUC by Ca2+ transient constitute a subset of ATP-responsive astrocytes that are activated in a neuron-independent way. In this study we show that GHB-evoked Ca2+ transients were also found to constitute a subset of ATP-responsive astrocytes in the NAc. Repetitive Ca2+ dynamics evoked by GHB suggested that Ca2+ was released from internal stores. Similarly to SUC, the GHB response was also characterized by an effective concentration of 50 μM. We observed that the number of ATP-responsive cells decreased with increasing concentration of either SUC or GHB. Moreover, the concentration dependence of the number of ATP-responsive cells were highly identical as a function of both [SUC] and [GHB], suggesting a mutual receptor for SUC and GHB, therefore implying the existence of a distinct GHB-recognizing astroglial SUC receptor in the brain. The SUC-evoked Ca2+ signal remained in mice lacking GABAB receptor type 1 subunit in the presence and absence of the N-Methyl-d-Aspartate (NMDA) receptor antagonist (2R)-amino-5-phosphonovaleric acid (APV), indicating action mechanisms independent of the GABAB or NMDA receptor subtypes. By molecular docking calculations we found that residues R99, H103, R252, and R281 of the binding crevice of the kidney SUC-responsive membrane receptor SUCNR1 (GPCR91) also predict interaction with GHB, further implying similar GHB and SUC action mechanisms. We conclude that the astroglial action of SUC and GHB may represent a link between brain energy states and Ca2+ signaling in astrocytic networks.

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“…Furthermore, we also reported on astroglial signaling independent of neuronal activity in acute brain slices isolated from the rat nucleus accumbens [10]. In general, neurons are more susceptible to oxidative injury than astrocytes, due to their limited antioxidant capacity [11].…”

Section: Introductionmentioning

confidence: 99%

“…Ψ MITO is also coupled to intracellular Ca 2+ regulation [11,13,14,16]. Changes in intracellular Ca 2+ level indicate activation of neuronal [17,18] or astroglial cells [10,19,20]. …”

Section: Introductionmentioning

confidence: 99%

Polyamidoamine dendrimer impairs mitochondrial oxidation in brain tissue

Nyitrai

Héja

Jablonkai

et al. 2013

Journal of Nanobiotechnology

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BackgroundThe potential nanocarrier polyamidoamine (PAMAM) generation 5 (G5-NH2) dendrimer has been shown to evoke lasting neuronal depolarization and cell death in a concentration-dependent manner. In this study we explored the early progression of G5-NH2 action in brain tissue on neuronal and astroglial cells.ResultsIn order to describe early mechanisms of G5-NH2 dendrimer action in brain tissue we assessed G5-NH2 trafficking, free intracellular Ca2+ and mitochondrial membrane potential (ΨMITO) changes in the rat hippocampal slice by microfluorimetry. With the help of fluorescent dye conjugated G5-NH2, we observed predominant appearance of the dendrimer in the plasma membrane of pyramidal neurons and glial cells within 30 min. Under this condition, G5-NH2 evoked robust intracellular Ca2+ enhancements and ΨMITO depolarization both in pyramidal neurons and astroglial cells. Intracellular Ca2+ enhancements clearly preceded ΨMITO depolarization in astroglial cells. Comparing activation dynamics, neurons and glia showed prevalence of lasting and transient ΨMITO depolarization, respectively. Transient as opposed to lasting ΨMITO changes to short-term G5-NH2 application suggested better survival of astroglia, as observed in the CA3 stratum radiatum area. We also showed that direct effect of G5-NH2 on astroglial ΨMITO was significantly enhanced by neuron-astroglia interaction, subsequent to G5-NH2 evoked neuronal activation.ConclusionThese findings indicate that the interaction of the PAMAM dendrimer with the plasma membrane leads to robust activation of neurons and astroglial cells, leading to mitochondrial depolarization. Distinguishable dynamics of mitochondrial depolarization in neurons and astroglia suggest that the enhanced mitochondrial depolarization followed by impaired oxidative metabolism of neurons may be the primary basis of neurotoxicity.

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Calcium signals in the nucleus accumbens: Activation of astrocytes by ATP and succinate

Cited by 24 publications

References 74 publications

Extensive astrocyte synchronization advances neuronal coupling in slow wave activity in vivo

Extensive astrocyte synchronization advances neuronal coupling in slow wave activity in vivo

Activation of astroglial calcium signaling by endogenous metabolites succinate and gamma-hydroxybutyrate in the nucleus accumbens

Polyamidoamine dendrimer impairs mitochondrial oxidation in brain tissue

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